TB28F400BVT80 [INTEL]
4-MBIT (256K X 16, 512K X 8)SmartVoltage BOOT BLOCK FLASH MEMORY FAMILY; 4兆位( 256K X 16 , 512K ×8 ) SmartVoltage BOOT BLOCK闪存系列型号: | TB28F400BVT80 |
厂家: | INTEL |
描述: | 4-MBIT (256K X 16, 512K X 8)SmartVoltage BOOT BLOCK FLASH MEMORY FAMILY |
文件: | 总57页 (文件大小:655K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
PRELIMINARY
E
4-MBIT (256K X 16, 512K X 8)
SmartVoltage BOOT BLOCK FLASH
MEMORY FAMILY
28F400BV-T/B, 28F400CV-T/B, 28F004BV-T/B
28F400CE-T/B, 28F004BE-T/B
Intel SmartVoltage Technology
5V or 12V Program/Erase
Extended Temperature Operation
–40°C to +85°C
2.7V, 3.3V or 5V Read Operation
Increased Programming Throughput
at 12V VPP
Extended Cycling Capability
100,000 Block Erase Cycles
(Commercial Temperature)
10,000 Block Erase Cycles
(Extended Temperature)
Very High-Performance Read
5V: 60/80/120 ns Max. Access Time,
30/40 ns Max. Output Enable Time
3V: 110/150/180 ns Max Access
65/90 ns Max. Output Enable Time
2.7V: 120 ns Max Access 65 ns Max.
Output Enable Time
Automated Word/Byte Program and
Block Erase
Industry-Standard Command User
Interface
Status Registers
Low Power Consumption
Max 60 mA Read Current at 5V
Max 30 mA Read Current at
2.7V–3.6V
Erase Suspend Capability
SRAM-Compatible Write Interface
Automatic Power Savings Feature
1 mA Typical ICC Active Current in
Static Operation
x8/x16-Selectable Input/Output Bus
28F400 for High Performance 16- or
32-bit CPUs
Reset/Deep Power-Down Input
0.2 µA ICCTypical
x8-Only Input/Output Architecture
28F004B for Space-Constrained
8-bit Applications
Provides Reset for Boot Operations
Hardware Data Protection Feature
Write Lockout during Power
Transitions
Optimized Array Blocking Architecture
One 16-KB Protected Boot Block
Two 8-KB Parameter Blocks
One 96-KB Main Block
Industry-Standard Surface Mount
Packaging
40-Lead TSOP
44-Lead PSOP: JEDEC ROM
Compatible
48-Lead TSOP
56-Lead TSOP
Three 128-KB Main Blocks
Top or Bottom Boot Locations
Absolute Hardware-Protection for Boot
Block
Software EEPROM Emulation with
Parameter Blocks
Footprint Upgradeable from 2-Mbit and
to 8-Mbit Boot Block Flash Memories
ETOX™ IV Flash Technology
July 1997
Order Number: 290530-005
Information in this document is provided in connection with Intel products. No license, express or implied, by estoppel or
otherwise, to any intellectual property rights is granted by this document. Except as provided in Intel’s Terms and Conditions of
Sale for such products, Intel assumes no liability whatsoever, and Intel disclaims any express or implied warranty, relating to
sale and/or use of Intel products including liability or warranties relating to fitness for a particular purpose, merchantability, or
infringement of any patent, copyright or other intellectual property right. Intel products are not intended for use in medical, life
saving, or life sustaining applications.
Intel may make changes to specifications and product descriptions at any time, without notice.
The 28F400BV-T/B, 28F400CV-T/B, 28F004BV-T/B, 28F400CE-T/B, 28F004BE-T/B may contain design defects or errors
known as errata which may cause the product to deviate from published specifications. Current characterized errata are
available on request.
Contact your local Intel sales office or your distributor to obtain the latest specifications and before placing your product order.
Copies of documents which have an ordering number and are referenced in this document, or other Intel literature, may be
obtained from:
Intel Corporation
P.O. Box 7641
Mt. Prospect, IL 60056-7641
or call 1-800-879-4683
or visit Intel’s Website at http:\\www.intel.com
COPYRIGHT © INTEL CORPORATION, 1997
CG-041493
*Third-party brands and names are the property of their respective owners.
E
4-MBIT SmartVoltage BOOT BLOCK FAMILY
CONTENTS
PAGE
PAGE
1.0 PRODUCT FAMILY OVERVIEW ....................5
3.5 Power Consumption...................................26
3.5.1 Active Power .......................................26
3.5.2 Automatic Power Savings (APS) .........26
3.5.3 Standby Power....................................26
3.5.4 Deep Power-Down Mode.....................26
3.6 Power-Up/Down Operation.........................26
3.6.1 RP# Connected to System Reset ........26
3.6.2 VCC, VPP and RP# Transitions.............27
3.7 Power Supply Decoupling ..........................27
3.7.1 VPP Trace on Printed Circuit Boards....27
1.1 New Features in the SmartVoltage
Products .....................................................5
1.2 Main Features..............................................5
1.3 Applications .................................................7
1.4 Pinouts.........................................................7
1.5 Pin Descriptions......................................... 11
2.0 PRODUCT DESCRIPTION............................ 13
2.1 Memory Blocking Organization .................. 13
2.1.1 Boot Block........................................... 13
2.1.2 Parameter Blocks................................ 13
2.1.3 Main Blocks......................................... 13
4.0 ABSOLUTE MAXIMUM RATINGS................28
5.0 COMMERCIAL OPERATING CONDITIONS.29
5.1 Applying VCC Voltages ...............................29
5.2 DC Characteristics .....................................30
5.3 AC Characteristics .....................................34
3.0 PRODUCT FAMILY PRINCIPLES OF
OPERATION ................................................ 15
3.1 Bus Operations.......................................... 15
3.2 Read Operations........................................ 15
3.2.1 Read Array.......................................... 15
3.2.2 Intelligent Identifiers ............................ 17
3.3 Write Operations........................................ 17
3.3.1 Command User Interface (CUI)........... 17
3.3.2 Status Register ................................... 20
3.3.3 Program Mode .................................... 21
3.3.4 Erase Mode......................................... 21
3.4 Boot Block Locking .................................... 22
3.4.1 VPP = VIL for Complete Protection ....... 22
3.4.2 WP# = VIL for Boot Block Locking ....... 22
6.0 EXTENDED OPERATING CONDITIONS......44
6.1 Applying VCC Voltages ...............................44
6.2 DC Characteristics .....................................45
6.3 AC Characteristics .....................................51
APENDIX A: Additional Information .................56
APPENDIX B: Additional Information...............57
3.4.3 RP# = VHH or WP# = VIH forr Boot Block
Unlocking........................................... 22
3.4.4 Upgrade Note for 8-Mbit 44-PSOP
Package............................................. 22
3
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E
REVISION HISTORY
Number
-001
Description
Initial release of datasheet.
-002
Status changed from Product Preview to Preliminary
28F400CV/CE/BE references and information added throughout.
2.7V CE/BE specs added throughout.
The following sections have been changed or rewritten: 1.1, 3.0, 3.2.1, 3.2.2, 3.3.1,
3.3.1.1, 3.3.2, 3.3.2.1, 3.3.3, 3.3.4, 3.6.2.
Note 2 added to Figure 3 to clarify 28F008B pinout vs. 28F008SA.
Sentence about program and erase WSM timeout deleted from Section 3.3.3, 3.3.4.
Erroneous arrows leading out of error states deleted from flowcharts in Figs. 9, 10.
Sections 5.1, 6.1 changed to “Applying VCC Voltages.” These sections completely
changed to clarify VCC ramp requirements.
I
PPD 3.3V Commercial spec changed from 10 to 5 µA.
Capacitance tables added after commercial and extended DC Characteristics tables.
Test and slew rate notes added to Figs. 12, 13, 19, 20, 21.
Test configuration drawings (Fig. 14, 22) consolidated into one, with component
values in table. (Component values also rounded off).
t
ELFL, tELFH, tAVFL changed from 7 to 5 ns for 3.3V BV-60 commercial and 3.3V
TBV-80 extended, 10 to 5 ns for 3.3V BV-80 and BV-120 commercial.
WHAX and tEHAX changed from 10 to 0 ns.
PHWL changed from 1000 ns to 800 ns for 3.3V BV-80, BV-120 commercial.
PHEL changed from 1000 ns to 800 ns for 3.3V BV-60, BV-80, and BV-120 commercial.
t
t
t
-003
-004
28F400BE row removed from Table 1
Applying VCC voltages (Sections 5.1 and 6.1) rewritten for clarity.
Minor cosmetic changes/edits.
Corrections: Spec typographical error “tQWL” corrected to read “tQVVL.”
Intel386™ EX Microprocessor block diagram updated because latest Intel386 CPU
specs require less glue logic.
Spec tELFL and tELFH changed from 5 ns (max) to 0 ns (min).
New specs tPLPH and tPLQX added from Specification Update document (297595).
Specs tEHQZ and tGHQZ improved on most voltage/speed combinations.
-005
Correction: Appendix A, Ordering information fixed order numbers from TE27F400BVT80
to TE28F400BVT80 and TE27F400BVB80 to TE28F400BVB80.
Updated disclaimer.
4
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E
4-MBIT SmartVoltage BOOT BLOCK FAMILY
1.0 PRODUCT FAMILY OVERVIEW
•
5V program/erase operation has been added.
If switching VPP for write protection, switch to
GND (not 5V) for complete write protection. To
take advantage of 5V write-capability, allow for
connecting 5V to VPP and disconnecting 12V
from VPP line.
This datasheet contains the specifications for the
two branches of products in the SmartVoltage
4-Mbit boot block flash memory family: the -BE/CE
suffix products feature a low VCC operating range
of 2.7V–3.6V; the -BV/CV suffix products offer
3.0V–3.6V operation. Both BE/CE and BV/CV
products also operate at 5V for high-speed access
times. Throughout this datasheet, the 28F400
refers to all x8/x16 4-Mbit products, while
28F004B refers to all x8 4-Mbit boot block
products. Also, the term “2.7V” generally refers to
•
Enhanced
circuits
optimize
low
VCC
performance, allowing operation down to
VCC = 2.7V (using the BE product).
If you are using BX/BL 12V VPP boot block
products today, you should account for the
differences listed above and also allow for
connecting 5V to VPP and disconnecting 12V from
the full voltage range 2.7V–3.6V. Section
provides an overview of the flash memory family
including applications, pinouts and pin
descriptions. Sections and describe the
1
V
PP line, if 5V writes are desired.
2
3
memory organization and operation for these
products. Finally, Sections 4 and 5 contain the
family’s operating specifications.
1.2
Main Features
Intel’s SmartVoltage technology is the most
flexible voltage solution in the flash industry,
providing two discrete voltage supply pins: VCC for
read operation, and VPP for program and erase
operation. Discrete supply pins allow system
designers to use the optimal voltage levels for
their design. The 28F400BV/CV, 28F004BV,
28F400CE and 28F004BE provide program/erase
capability at 5V or 12V. The 28F400BV/CV and
28F004BV allow reads with VCC at 3.3 ± 0.3V or
5V, while the 28F400CE and 28F004BE allow
reads with VCC at 2.7V–3.6V or 5V. Since many
designs read from the flash memory a large
percentage of the time, read operation using the
2.7V or 3.3V ranges can provide great power
savings. If read performance is an issue, however,
5V VCC provides faster read access times.
1.1
New Features in the
SmartVoltage Products
The SmartVoltage boot block flash memory family
offers identical operation with the BX/BL 12V
program products, except for the differences listed
below. All other functions are equivalent to current
products, including signatures, write commands,
and pinouts.
•
WP# pin has replaced a DU (Don’t Use) pin.
Connect the WP# pin to control signal or to
VCC or GND (in this case, a logic-level signal
can be placed on DU pin). See Tables 2 and
9 to see how the WP# pin works.
Table 1. SmartVoltage Provides Total Voltage Flexibility
Product
Name
Bus
VCC
VPP
Width
2.7V–3.6V
3.3 ± 0.3V
5V ± 5%
5V ± 10%
5V ± 10%
12V ± 5%
28F004BV-T/B
28F400BV-T/B
x8
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
x8 or x16
28F400CV-T/B x8 or x16
28F004BE-T/B x8
√
√
28F400CE-T/B x8 or x16
5
PRELIMINARY
4-MBIT SmartVoltage BOOT BLOCK FAMILY
E
For program and erase operations, 5V VPP
operation eliminates the need for in system voltage
converters, while 12V VPP operation provides faster
program and erase for situations where 12V is
available, such as manufacturing or designs where
12V is in-system. For design simplicity, however,
just hook up VCC and VPP to the same 5V ± 10%
source.
Each byte or word in the flash memory can be
programmed independently of other memory
locations, unlike erases, which erase all locations
within a block simultaneously.
The 4-Mbit SmartVoltage boot block flash memory
family is also designed with an Automatic Power
Savings (APS) feature which minimizes system
battery current drain, allowing for very low power
designs. To provide even greater power savings,
the boot block family includes a deep power-down
mode which minimizes power consumption by
turning most of the flash memory’s circuitry off.
This mode is controlled by the RP# pin and its
usage is discussed in Section 3.5, along with other
power consumption issues.
The 28F400/28F004B boot block flash memory
family is a high-performance, 4-Mbit (4,194,304 bit)
flash memory family organized as either
256 Kwords of 16 bits each (28F400 only) or
512 Kbytes of 8 bits each (28F400 and 28F004B).
Separately erasable blocks, including a hardware-
lockable boot block (16,384 bytes), two parameter
blocks (8,192 bytes each) and main blocks (one
block of 98,304 bytes and three blocks of 131,072
bytes), define the boot block flash family
architecture. See Figures 7 and 8 for memory
maps. Each block can be independently erased and
programmed 100,000 times at commercial
temperature or 10,000 times at extended
temperature.
Additionally, the RP# pin provides protection
against unwanted command writes due to invalid
system bus conditions that may occur during
system reset and power-up/down sequences. For
example, when the flash memory powers-up, it
automatically defaults to the read array mode, but
during
a
warm system reset, where power
continues uninterrupted to the system components,
the flash memory could remain in a non-read mode,
such as erase. Consequently, the system Reset
signal should be tied to RP# to reset the memory to
normal read mode upon activation of the Reset
signal. See Section 3.6.
The boot block is located at either the top (denoted
by -T suffix) or the bottom (-B suffix) of the address
map in order to accommodate different
microprocessor protocols for boot code location.
The hardware-lockable boot block provides
complete code security for the kernel code required
for system initialization. Locking and unlocking of
the boot block is controlled by WP# and/or RP#
(see Section 3.4 for details).
The 28F400 provides both byte-wide or word-wide
input/output, which is controlled by the BYTE# pin.
Please see Table 2 and Figure 16 for a detailed
description of BYTE# operations, especially the
usage of the DQ
15/A–1 pin.
The Command User Interface (CUI) serves as the
interface
between
the
microprocessor
or
The 28F400 products are available in
a
microcontroller and the internal operation of the
boot block flash memory products. The internal
Write State Machine (WSM) automatically executes
the algorithms and timings necessary for program
and erase operations, including verifications,
thereby unburdening the microprocessor or
microcontroller of these tasks. The Status Register
(SR) indicates the status of the WSM and whether it
successfully completed the desired program or
erase operation.
ROM/EPROM-compatible pinout and housed in the
44-lead PSOP (Plastic Small Outline) package, the
48-lead TSOP (Thin Small Outline, 1.2 mm thick)
package and the 56-lead TSOP as shown in
Figures 4, 5 and 6, respectively. The 28F004
products are available in the 40-lead TSOP
package as shown in Figure 3.
Refer to the DC Characteristics Table, Section 5.2
(commercial temperature) and Section 6.2
(extended temperature), for complete current and
voltage specifications. Refer to the AC
Characteristics Table, Section 5.3 (commercial
Program and Erase Automation allows program and
erase operations to be executed using an industry-
standard two-write command sequence to the CUI.
Data writes are performed in word (28F400 family)
or byte (28F400 or 28F004B families) increments.
temperature)
and
Section
6.3
(extended
temperature), for read, write and erase performance
specifications.
6
PRELIMINARY
E
4-MBIT SmartVoltage BOOT BLOCK FAMILY
The 4-Mbit flash memory products are also
excellent design solutions for digital cellular phone
and telecommunication switching applications
requiring very low power consumption, high-
performance, high-density storage capability,
modular software designs, and a small form factor
package. The 4-Mbit’s blocking scheme allows for
easy segmentation of the embedded code with
16 Kbytes of hardware-protected boot code, four
main blocks of program code and two parameter
blocks of 8 Kbytes each for frequently updated data
storage and diagnostic messages (e.g., phone
numbers, authorization codes).
1.3
Applications
The 4-Mbit boot block flash memory family
combines
high-density,
low-power,
high-
performance, cost-effective flash memories with
blocking and hardware protection capabilities. Their
flexibility and versatility reduce costs throughout the
product life cycle. Flash memory is ideal for Just-In-
Time production flow, reducing system inventory
and costs, and eliminating component handling
during the production phase.
When your product is in the end-user’s hands, and
updates or feature enhancements become
necessary, flash memory reduces the update costs
by allowing user-performed code changes instead
of costly product returns or technician calls.
Intel’s boot block architecture provides a flexible
voltage solution for the different design needs of
various applications. The asymmetrically-blocked
memory map allows the integration of several
memory components into a single flash device. The
boot block provides a secure boot PROM; the
The 4-Mbit boot block flash memory family provides
full-function, blocked flash memories suitable for a
wide range of applications. These applications
include extended PC BIOS and ROM-able
applications storage, digital cellular phone program
and data storage, telecommunication boot/firmware,
printer firmware/font storage and various other
embedded applications where program and data
storage are required.
parameter
blocks
can
emulate
EEPROM
functionality for parameter store with proper
software techniques; and the main blocks provide
code and data storage with access times fast
enough to execute code in place, decreasing RAM
requirements.
Reprogrammable systems, such as personal
computers, are ideal applications for the 4-Mbit
flash memory products. Increasing software
sophistication greatens the probability that a code
update will be required after the PC is shipped. For
example, the emerging of “plug and play” standard
in desktop and portable PCs enables auto-
configuration of ISA and PCI add-in cards.
However, since the “plug and play” specification
continues to evolve, a flash BIOS provides a cost-
effective capability to update existing PCs. In
addition, the parameter blocks are ideal for storing
1.4
Pinouts
Intel’s SmartVoltage Boot Block architecture
provides upgrade paths in every package pinout to
the 8-Mbit density. The 28F004B 40-lead TSOP
pinout for space-constrained designs is shown in
Figure 3. The 28F400 44-lead PSOP pinout follows
the industry-standard ROM/EPROM pinout, as
shown in Figure 4. For designs that require x16
operation but have space concerns, refer to the
48-lead pinout in Figure 5. Furthermore, the 28F400
56-lead TSOP pinout shown in Figure 6 provides
density upgrades to future higher density boot block
memories.
the
allowing you to integrate the BIOS PROM and
parameter storage EEPROM into single
required
auto-configuration
parameters,
a
component, reducing parts costs while increasing
functionality.
Pinouts for the corresponding 2-Mbit and 8-Mbit
components are also provided for convenient
reference. 4-Mbit pinouts are given on the chip
illustration in the center, with 2-Mbit and 8-Mbit
pinouts going outward from the center.
7
PRELIMINARY
4-MBIT SmartVoltage BOOT BLOCK FAMILY
E
A[18:1]
A[0:17]
CS#
RD#
WR#
CE#
OE#
WE#
i386™ EX CPU
(25 MHz)
28F400BV-60
D[0:15]
RESET
DQ[0:15]
RP#
RESET
0530_01
NOTE:
A data bus buffer may be needed for processor speeds above 25 MHz.
Figure 1. 28F400 Interface to Intel386™ EX Microprocessor
ADDRESS
LATCHES
A[16:18]
LE
A8-A15
80C188EB
A0-A18
ALE
28F004-T
ADDRESS
LATCHES
AD0-AD7
LE
DQ0-DQ7
CE#
UCS#
VCC
10K
Ω
WR#
RD#
WE#
OE#
RESIN#
RP#
VCC
System Reset
VPP
P1.X
P1.X
WP#
0530_02
Figure 2. 28F004B Interface to Intel80C188EB 8-Bit Embedded Microprocessor
8
PRELIMINARY
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4-MBIT SmartVoltage BOOT BLOCK FAMILY
28F008B 28F002B
28F002B 28F008B
A
A
A
A
A
A
A
A
A
A
A
A
A
GND
NC
NC
A
A
GND
NC
NC
A
A
17
GND
NC
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
40
39
38
37
36
17
17
16
15
14
16
15
14
16
15
14
13
12
11
A
A
A
A
A
A
A
A
13
12
11
13
12
11
19
10
10
10
DQ
DQ
6
DQ
DQ
DQ
6
DQ
DQ
DQ
DQ
35
34
33
32
31
30
29
28
27
26
25
24
23
22
21
7
7
7
6
5
4
A
A
A
A
A
A
9
8
9
8
9
8
28F004B
Boot Block
40-Lead TSOP
10 mm x 20 mm
5
4
5
4
WE#
WE# WE#
DQ
V
DQ
V
DQ
V
RP#
PP
RP#
PP
RP#
CC
CC
CC
CC
CC
V
V
V
V
V
V
PP
CC
NC
DQ
DQ
DQ
DQ
OE#
GND
CE#
NC
DQ
DQ
DQ
DQ
OE#
GND
CE#
NC
DQ
DQ
DQ
DQ
OE#
GND
CE#
WP#
WP# WP#
A
A
A
A
A
A
A
A
A
NC
18
18
3
2
1
0
3
2
1
0
3
2
1
0
TOP VIEW
A
7
A
7
7
6
5
4
A
A
5
A
A
A
5
A
6
6
4
4
A
3
2
A
3
2
3
2
A
A
A
A
A
A
A
1
1
1
0
0
0
0530_03
Figure 3. The 40-Lead TSOP Offers the Smallest Form Factor for Space-Constrained Applications
28F800 28F200
28F200
28F800
1
2
3
4
44
43
42
41
40
39
38
37
RP#
WE#
A8
A9
A10
A11
A12
A13
A14
RP#
WE#
A8
A9
A10
A11
A12
A13
A14
A15
A16
BYTE#
GND
RP#
WE#
A8
A9
A10
A11
A12
A13
A14
VPP
A18
A17
A 7
A 6
A 5
A 4
A 3
A 2
A 1
A 0
CE#
GND
OE#
VPP
WP#
NC
A 7
A 6
A 5
A 4
A 3
A 2
A 1
A 0
CE#
GND
OE#
VPP
WP#
A17
A 7
A 6
A 5
A 4
A 3
A 2
A 1
A 0
CE#
GND
OE#
5
6
7
8
9
10
11
12
13
14
15
16
PA28F400
Boot Block
44-Lead PSOP
0.525" x 1.110"
36
35
A15
A16
A15
A16
34
33
32
31
30
29
BYTE#
GND
DQ15 /A-1 DQ15 /A-1
BYTE#
GND
DQ15 /A-1
DQ7
DQ14
DQ6
DQ13
DQ5
DQ12
DQ4
VCC
TOP VIEW
DQ7
DQ14
DQ6
DQ13
DQ5
DQ12
DQ4
VCC
DQ7
DQ14
DQ6
DQ13
DQ5
DQ12
DQ4
VCC
DQ0
DQ8
DQ1
DQ9
DQ2
DQ10
DQ3
DQ11
DQ0
DQ8
DQ1
DQ9
DQ2
DQ10
DQ3
DQ11
DQ0
DQ8
DQ1
DQ9
DQ2
DQ10
DQ3
DQ11
17
18
19
20
21
22
28
27
26
25
24
23
0530_04
NOTE: Pin 2 is WP# on 2- and 4-Mbit devices but A18 on the 8-Mbit because no other pins were available for the high order
address. Thus, the 8-Mbit in the 44-lead PSOP cannot unlock the boot block without RP# = VHH (12V). To allow upgrades to
the 8 Mbit from 2/2 Mbit in this package, design pin 2 to control WP# at the 2/4 Mbit level and A18 at the 8-Mbit density. See
Section 3.4 for details.
Figure 4. The 44-Lead PSOP Offers a Convenient Upgrade from JEDEC ROM Standards
9
PRELIMINARY
4-MBIT SmartVoltage BOOT BLOCK FAMILY
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28F200
28F800
28F800
28F200
A16
BYTE#
GND
A16
BYTE#
GND
A16
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
A15
A14
A13
A12
A11
A10
A9
A15
A14
A13
A12
A11
A10
A9
A15
A14
A13
A12
A11
A10
A9
1
2
3
4
5
6
7
8
BYTE#
GND
DQ15 /A-1
DQ7
DQ14
DQ6
DQ13
DQ5
DQ12
DQ4
VCC
DQ15 /A-1 DQ15 /A-1
DQ7
DQ14
DQ6
DQ13
DQ5
DQ12
DQ4
VCC
DQ11
DQ3
DQ10
DQ2
DQ9
DQ1
DQ8
DQ0
OE#
GND
CE#
A0
DQ7
DQ14
DQ6
DQ13
DQ5
DQ12
DQ4
VCC
A8
A8
A8
NC
NC
WE#
RP#
VPP
WP#
NC
A18
A17
A7
A6
A5
A4
A3
NC
NC
NC
NC
9
28F400
Boot Block
48-Lead TSOP
12 mm x 20 mm
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
WE# WE#
RP#
VPP
RP#
VPP
DQ11
DQ3
DQ10
DQ2
DQ9
DQ1
DQ8
DQ0
OE#
GND
CE#
A0
DQ11
DQ3
DQ10
DQ2
DQ9
DQ1
DQ8
DQ0
OE#
GND
CE#
WP# WP#
NC
NC
NC
A 7
A 6
A 5
A 4
A 3
A 2
A 1
NC
NC
A17
A7
A6
A5
A4
A3
A2
A1
TOP VIEW
A2
A1
A0
0530_05
Figure 5. The 48-Lead TSOP Offers the Smallest Form Factor for x16 Operation
28F200
28F200
NC
NC
NC
NC
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
NC
16
BYTE#
GND
DQ /A
NC
16
BYTE#
GND
A
A
A
A
15
14
13
12
15
14
13
12
11
A
A
A
A
A
A
A
A
DQ /A
15 -1
15 -1
DQ
DQ
7
7
11
DQ
DQ
DQ
DQ
14
6
13
14
A
A
A
8
A
A
A
DQ
6
10
9
10
9
8
DQ
13
DQ
DQ
DQ
V
DQ
5
5
12
28F400
56-Lead TSOP
Boot Block
NC
NC
WE#
RP#
NC
NC
NC
WE#
RP#
NC
DQ
DQ
4
12
4
V
CC
CC
CC
V
V
DQ
14 mm x 20 mm
CC
DQ
DQ
DQ
DQ
DQ
DQ
DQ
DQ
11
3
10
2
9
1
11
DQ
3
NC
NC
TOP VIEW
V
V
DQ
DQ
2
DQ
DQ
1
DQ
DQ
0
OE#
PP
PP
10
WP#
NC
WP#
NC
9
A
NC
17
A
7
A
A
6
A
A
4
A
A
2
7
8
0
8
A
A
5
A
6
OE#
GND
CE#
5
4
GND
CE#
33
32
31
30
29
A
3
3
A
2
A
NC
NC
A
NC
NC
0
0
A
1
NC
A
1
NC
0530_06
Figure 6. The 56-Lead TSOP Offers Compatibility between 2 and 4 Mbits
10
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4-MBIT SmartVoltage BOOT BLOCK FAMILY
1.5
Pin Descriptions
Table 2. 28F400/004 Pin Descriptions
Symbol
Type
Name and Function
ADDRESS INPUTS for memory addresses. Addresses are internally latched
during a write cycle. The 28F400 only has A0– A17 pins, while the 28F004B
A0–A18
INPUT
has A0– A18
.
A9
INPUT
ADDRESS INPUT: When A9 is at VHH the signature mode is accessed. During
this mode, A0 decodes between the manufacturer and device IDs. When BYTE#
is at a logic low, only the lower byte of the signatures are read. DQ15/A–1 is a
don’t care in the signature mode when BYTE# is low.
DQ0–DQ7
DQ8–DQ15
INPUT/ DATA INPUTS/OUTPUTS: Inputs array data on the second CE# and WE# cycle
OUTPUT during a Program command. Inputs commands to the Command User Interface
when CE# and WE# are active. Data is internally latched during the write cycle.
Outputs array, Intelligent Identifier and Status Register data. The data pins float to
tri-state when the chip is de-selected or the outputs are disabled.
INPUT/ DATA INPUTS/OUTPUTS: Inputs array data on the second CE# and WE# cycle
OUTPUT during a Program command. Data is internally latched during the write cycle.
Outputs array data. The data pins float to tri-state when the chip is de-selected or
the outputs are disabled as in the byte-wide mode (BYTE# = “0”). In the byte-wide
mode DQ15/A–1 becomes the lowest order address for data output on DQ0–DQ7.
The 28F004B does not include these DQ8–DQ15 pins.
CE#
INPUT
CHIP ENABLE: Activates the device’s control logic, input buffers, decoders and
sense amplifiers. CE# is active low. CE# high de-selects the memory device and
reduces power consumption to standby levels. If CE# and RP# are high, but not
at a CMOS high level, the standby current will increase due to current flow
through the CE# and RP# input stages.
OE#
WE#
INPUT
INPUT
OUTPUT ENABLE: Enables the device’s outputs through the data buffers during
a read cycle. OE# is active low.
WRITE ENABLE: Controls writes to the Command Register and array blocks.
WE# is active low. Addresses and data are latched on the rising edge of the WE#
pulse.
RP#
INPUT
RESET/DEEP POWER-DOWN: Uses three voltage levels (VIL, VIH, and VHH) to
control two different functions: reset/deep power-down mode and boot block
unlocking. It is backwards-compatible with the BX/BL/BV products.
When RP# is at logic low, the device is in reset/deep power-down mode,
which puts the outputs at High-Z, resets the Write State Machine, and draws
minimum current.
When RP# is at logic high, the device is in standard operation. When RP#
transitions from logic-low to logic-high, the device defaults to the read array mode.
When RP# is at VHH, the boot block is unlocked and can be programmed or
erased. This overrides any control from the WP# input.
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Table 2. 28F400/004 Pin Descriptions (Continued)
Name and Function
Symbol
WP#
Type
INPUT
WRITE PROTECT: Provides a method for unlocking the boot block in a system
without a 12V supply.
When WP# is at logic low, the boot block is locked, preventing program and
erase operations to the boot block. If a program or erase operation is attempted
on the boot block when WP# is low, the corresponding status bit (bit 4 for
program, bit 5 for erase) will be set in the Status Register to indicate the operation
failed.
When WP# is at logic high, the boot block is unlocked and can be
programmed or erased.
NOTE: This feature is overridden and the boot block unlocked when RP# is at
V
HH. See Section 3.4 for details on write protection.
BYTE#
INPUT
BYTE# ENABLE: Not available on 28F004B. Controls whether the device
operates in the byte-wide mode (x8) or the word-wide mode (x16). BYTE# pin
must be controlled at CMOS levels to meet the CMOS current specification in the
standby mode.
When BYTE# is at logic low, the byte-wide mode is enabled, where data is
read and programmed on DQ0–DQ7 and DQ15/A–1 becomes the lowest order
address that decodes between the upper and lower byte. DQ8–DQ14 are tri-stated
during the byte-wide mode.
When BYTE# is at logic high, the word-wide mode is enabled, where data is
read and programmed on DQ0–DQ15
.
VCC
VPP
DEVICE POWER SUPPLY: 5.0V ± 10%, 3.3 ± 0.3V, 2.7V–3.6V (BE/CE only)
PROGRAM/ERASE POWER SUPPLY: For erasing memory array blocks or
programming data in each block, a voltage either of 5V ± 10% or 12V ± 5% must
be applied to this pin. When VPP < VPPLK all blocks are locked and protected
against Program and Erase commands.
GND
NC
GROUND: For all internal circuitry.
NO CONNECT: Pin may be driven or left floating.
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4-MBIT SmartVoltage BOOT BLOCK FAMILY
2.1.2 TWO 8-KB PARAMETER BLOCKS
2.0 PRODUCT DESCRIPTION
The boot block architecture includes parameter
blocks to facilitate storage of frequently updated
small parameters that would normally require an
EEPROM. By using software techniques, the byte-
rewrite functionality of EEPROMs can be emulated.
These techniques are detailed in Intel’s application
note, AP-604 Using Intel’s Boot Block Flash
Memory Parameter Blocks to Replace EEPROM.
Each boot block component contains two parameter
2.1
Memory Blocking Organization
This product family features an asymmetrically-
blocked architecture providing system memory
integration. Each erase block can be erased
independently of the others up to 100,000 times for
commercial temperature or up to 10,000 times for
extended temperature. The block sizes have been
chosen to optimize their functionality for common
applications of nonvolatile storage. The combination
of block sizes in the boot block architecture allow
the integration of several memories into a single
chip. For the address locations of the blocks, see
the memory maps in Figures 4 and 5.
blocks of
8 Kbytes (8,192 bytes) each. The
parameter blocks are not write-protectable.
2.1.3
ONE 96-KB + THREE 128-KB
MAIN BLOCKS
After the allocation of address space to the boot
and parameter blocks, the remainder is divided into
main blocks for data or code storage. Each 4-Mbit
device contains one 96-Kbyte (98,304 byte) block
and three 128-Kbyte (131,072 byte) blocks. See the
memory maps for each device for more information.
2.1.1
ONE 16-KB BOOT BLOCK
The boot block is intended to replace a dedicated
boot PROM in a microprocessor or microcontroller-
based system. The 16-Kbyte (16,384 bytes) boot
block is located at either the top (denoted by -T
suffix) or the bottom (-B suffix) of the address map
to accommodate different microprocessor protocols
for boot code location. This boot block features
hardware controllable write-protection to protect the
crucial microprocessor boot code from accidental
modification. The protection of the boot block is
controlled using a combination of the VPP, RP#, and
WP# pins, as is detailed in Section 3.4.
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28F400-T
28F400-B
3FFFFH
3FFFFH
16-Kbyte BOOT BLOCK
128-Kbyte MAIN BLOCK
3E000H
8-Kbyte PARAMETER BLOCK
8-Kbyte PARAMETER BLOCK
3DFFFH
30000H
2FFFFH
3D000H
3CFFFH
128-Kbyte MAIN BLOCK
3C000H
3BFFFH
20000H
1FFFFH
96-Kbyte MAIN BLOCK
128-Kbyte MAIN BLOCK
30000H
2FFFFH
128-Kbyte MAIN BLOCK
10000H
0FFFFH
96-Kbyte MAIN BLOCK
20000H
1FFFFH
04000H
03FFFH
128-Kbyte MAIN BLOCK
128-Kbyte MAIN BLOCK
8-Kbyte PARAMETER BLOCK
8-Kbyte PARAMETER BLOCK
03000H
10000H
0FFFFH
02FFFH
02000H
01FFFH
16-Kbyte BOOT BLOCK
00000H
00000H
0530_07
NOTE: Address = A[17:0]. In x8 operation, the least significant system address should be connected to A . Memory maps are
-1
shown for x16 operation.
Figure 7. Word-Wide x16-Mode Memory Maps
28F004-B
28F004-T
7FFFFH
7FFFFH
16-Kbyte BOOT BLOCK
128-Kbyte MAIN BLOCK
128-Kbyte MAIN BLOCK
7C000H
7BFFFH
7A000H
79FFFH
78000H
77FFFH
60000H
5FFFFH
8-Kbyte PARAMETER BLOCK
8-Kbyte PARAMETER BLOCK
40000H
3FFFFH
96-Kbyte MAIN BLOCK
128-Kbyte MAIN BLOCK
60000H
5FFFFH
128-Kbyte MAIN BLOCK
96-Kbyte MAIN BLOCK
20000H
1FFFFH
40000H
3FFFFH
08000H
07FFFH
06000H
05FFFH
04000H
03FFFH
128-Kbyte MAIN BLOCK
128-Kbyte MAIN BLOCK
8-Kbyte PARAMETER BLOCK
8-Kbyte PARAMETER BLOCK
20000H
1FFFFH
16-Kbyte BOOT BLOCK
00000H
00000H
0530_08
NOTE: Address = A[18:0]. These memory maps apply to the 28F004B or the 28F400 in x8 mode.
Figure 8. Byte-Wide x8-Mode Memory Maps
14
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4-MBIT SmartVoltage BOOT BLOCK FAMILY
3.0 PRODUCT FAMILY PRINCIPLES
OF OPERATION
3.2
Read Operations
3.2.1
READ ARRAY
Flash memory combines EPROM functionality with
in-circuit electrical write and erase. The boot block
flash family utilizes a Command User Interface
(CUI) and automated algorithms to simplify write
and erase operations. The CUI allows for 100%
TTL-level control inputs, fixed power supplies
during erasure and programming, and maximum
EPROM compatibility.
When RP# transitions from VIL (reset) to VIH, the
device will be in the read array mode and will
respond to the read control inputs (CE#, address
inputs, and OE#) without any commands being
written to the CUI.
When the device is in the read array mode, five
control signals must be controlled to obtain data at
the outputs.
When VPP < VPPLK, the device will only successfully
execute the following commands: Read Array,
Read Status Register, Clear Status Register and
intelligent identifier mode. The device provides
standard EPROM read, standby and output disable
operations. Manufacturer identification and device
identification data can be accessed through the CUI
or through the standard EPROM A9 high voltage
access (VID) for PROM programming equipment.
•
•
•
•
•
RP# must be logic high (VIH)
WE# must be logic high (VIH)
BYTE# must be logic high or logic low
CE# must be logic low (VIL)
OE must be logic low (VIL)
The same EPROM read, standby and output
disable functions are available when 5V or 12V is
applied to the VPP pin. In addition, 5V or 12V on
VPP allows write and erase of the device. All
functions associated with altering memory contents:
Program and Erase, Intelligent Identifier Read, and
Read Status are accessed via the CUI.
In addition, the address of the desired location must
be applied to the address pins. Refer to Figures 15
and 16 for the exact sequence and timing of these
signals.
If the device is not in read array mode, as would be
the case after a program or erase operation, the
Read Mode command (FFH) must be written to the
CUI before reads can take place.
The internal Write State Machine (WSM) completely
automates program and erase, beginning operation
signaled by the CUI and reporting status through
the Status Register. The CUI handles the WE#
interface to the data and address latches, as well
as system status requests during WSM operation.
During system design, consideration should be
taken to ensure address and control inputs meet
required input slew rates of <10 ns as defined in
Figures 12 and 13.
3.1
Bus Operations
Flash memory reads, erases and writes in-system
via the local CPU. All bus cycles to or from the flash
memory conform to standard microprocessor bus
cycles. These bus operations are summarized in
Tables 3 and 4.
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Table 3. Bus Operations for Word-Wide Mode (BYTE# = VIH
)
Mode
Notes
RP#
VIH
VIH
VIH
VIL
CE#
VIL
VIL
VIH
X
OE#
VIL
VIH
X
WE#
VIH
VIH
X
A9
X
A0
X
VPP
X
DQ0–15
DOUT
Read
1,2,3
Output Disable
Standby
X
X
X
High Z
High Z
High Z
0089 H
X
X
X
Deep Power-Down
9
4
X
X
X
X
X
Intelligent Identifier
(Mfr)
VIH
VIL
VIL
VIH
VID
VIL
X
Intelligent Identifier
(Device)
4,5
VIH
VIH
VIL
VIL
VIL
VIH
VIH
VIL
VID
X
VIH
X
X
X
See
Table 5
Write
6,7,8
DIN
Table 4. Bus Operations for Byte-Wide Mode (BYTE# = VIL)
Mode
Read
Notes RP#
CE#
VIL
OE# WE#
A9
X
A0
X
A–1
X
VPP
X
DQ0–7 DQ8–14
DOUT High Z
1,2,3
VIH
VIH
VIL
VIH
VIH
VIH
Output
VIL
X
X
X
X
High Z High Z
Disable
Standby
VIH
VIL
VIH
X
X
X
X
X
X
X
X
X
X
X
X
X
High Z High Z
High Z High Z
Deep Power-
Down
9
4
Intelligent
Identifier (Mfr)
VIH
VIH
VIL
VIL
VIL
VIL
VIH
VIH
VID
VID
VIL
VIH
X
X
X
X
89H
High Z
High Z
Intelligent
Identifier
(Device)
4,5
See
Table
5
Write
6,7,8
VIH
VIL
VIH
VIL
X
X
X
X
DIN
High Z
NOTES:
1. Refer to DC Characteristics.
2. X can be VIL, VIH for control pins and addresses, VPPLK or VPPH for VPP
.
3. See DC Characteristics for VPPLK, VPPH1, VPPH2, VHH, VID voltages.
4. Manufacturer and device codes may also be accessed via a CUI write sequence, A –A17 = X, A1–A18 = X.
1
5. See Table 5 for device IDs.
6. Refer to Table 7 for valid DIN during a write operation.
7. Command writes for block erase or word/byte program are only executed when VPP = VPPH1 or VPPH2
8. To write or erase the boot block, hold RP# at VHH or WP# at VIH. See Section 3.4.
.
9. RP# must be at GND ± 0.2V to meet the maximum deep power-down current specified.
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4-MBIT SmartVoltage BOOT BLOCK FAMILY
3.2.2
INTELLIGENT IDENTIFIERS
3.3
Write Operations
To read the manufacturer and device codes, the
device must be in intelligent identifier read mode,
which can be reached using two methods: by
writing the intelligent identifier command (90H) or
by taking the A9 pin to VID. Once in intelligent
identifier read mode, A0 = 0 outputs the manu-
facturer’s identification code and A0 = 1 outputs the
device code. In byte-wide mode, only the lower byte
of the above signatures is read (DQ15/A–1 is a
“don’t care” in this mode). See Table 5 for product
signatures. To return to read array mode, write a
Read Array command (FFH).
3.3.1
COMMAND USER INTERFACE (CUI)
The Command User Interface (CUI) is the interface
between the microprocessor and the internal chip
controller. Commands are written to the CUI using
standard microprocessor write timings. The
available commands are Read Array, Read
Intelligent Identifier, Read Status Register, Clear
Status Register, Erase and Program (summarized
in Tables 6 and 7). The three read modes are read
array, intelligent identifier read, and status register
read. For Program or Erase commands, the CUI
informs the Write State Machine (WSM) that a write
or erase has been requested. During the execution
of a Program command, the WSM will control the
programming sequences and the CUI will only
respond to status reads. During an erase cycle, the
CUI will respond to status reads and erase
suspend. After the WSM has completed its task, it
will set the WSM Status bit to a “1” (ready), which
indicates that the CUI can respond to its full
command set. Note that after the WSM has
returned control to the CUI, the CUI will stay in the
current command state until it receives another
command.
Table 5. Intelligent Identifier Table
Product
Mfr. ID
Device ID
-T
-B
(Top Boot) (Bottom Boot)
28F400
28F004
0089 H
89 H
4470 H
78 H
4471 H
79 H
3.3.1.1
Command Function Description
Device operations are selected by writing specific
commands into the CUI. Tables 6 and 7 define the
available commands.
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Table 6. Command Codes and Descriptions
Decription
Code Device Mode
00
FF
40
Invalid/
Reserved
Unassigned commands that should not be used. Intel reserves the right to redefine
these codes for future functions.
Read Array Places the device in read array mode, so that array data will be output on the data
pins.
Program
Set-Up
Sets the CUI into a state such that the next write will latch the Address and Data
registers on the rising edge and begin the program algorithm. The device then
defaults to the read status mode, where the device outputs Status Register data
when OE# is enabled. To read the array, issue a Read Array command.
To cancel a program operation after issuing a Program Set-Up command, write all
1’s (FFH for x8, FFFFH for x16) to the CUI. This will return to read status register
mode after a standard program time without modifying array contents. If a program
operation has already been initiated to the WSM this command can not cancel that
operation in progress.
10
20
Alternate
Prog Set-Up
(See 40H/Program Set-Up)
Erase
Set-Up
Prepares the CUI for the Erase Confirm command. If the next command is not an
Erase Confirm command, then the CUI will set both the Program Status (SR.4) and
Erase Status (SR.5) bits of the Status Register to a “1,” place the device into the
read Status Register state, and wait for another command without modifying array
contents. This can be used to cancel an erase operation after the Erase Setup
command has been issued. If an operation has already been initiated to the WSM
this can not cancel that operation in progress.
D0
B0
Erase
Resume/
Erase
If the previous command was an Erase Set-Up command, then the CUI will latch
address and data, and begin erasing the block indicated on the address pins.
During erase, the device will respond only to the Read Status Register and Erase
Suspend commands and will output Status Register data when OE# is toggled low.
Status Register data is updated by toggling either OE# or CE# low.
Confirm
Erase
Suspend
Valid only while an erase operation is in progress and will be ignored in any other
circumstance. Issuing this command will begin to suspend erase operation. The
Status Register will indicate when the device reaches erase suspend mode. In this
mode, the CUI will respond only to the Read Array, Read Status Register, and
Erase Resume commands and the WSM will also set the WSM Status bit to a “1”
(ready). The WSM will continue to idle in the SUSPEND state, regardless of the
state of all input control pins except RP#, which will immediately shut down the
WSM and the remainder of the chip, if it is made active. During a suspend
operation, the data and address latches will remain closed, but the address pads
are able to drive the address into the read path. See Section 3.3.4.1.
70
Read Status Puts the device into the read Status Register mode, so that reading the device
Register
outputs Status Register data, regardless of the address presented to the device.
The device automatically enters this mode after program or erase has completed.
This is one of the two commands that is executable while the WSM is operating.
See Section 3.3.2.
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Table 6. Command Codes and Descriptions (Continued)
Decription
Code Device Mode
50
Clear Status The WSM can only set the Program Status and Erase Status bits in the Status
Register
Register to “1;” it cannot clear them to “0.”
The Status Register operates in this fashion for two reasons. The first is to give the
host CPU the flexibility to read the status bits at any time. Second, when
programming a string of bytes, a single Status Register query after programming
the string may be more efficient, since it will return the accumulated error status of
the entire string. See Section 3.3.2.1.
90
Intelligent
Identifier
Puts the device into the intelligent identifier read mode, so that reading the device
will output the manufacturer and device codes. (A0 = 0 for manufacturer,
A0 = 1 for device, all other address inputs are ignored). See Section 3.2.2.
Table 7. Command Bus Definitions
First Bus Cycle
Second Bus Cycle
Command
Note
8
Oper
Write
Write
Write
Write
Write
Write
Addr
X
Data
Oper
Addr
Data
Read Array
FFH
90H
70H
50H
40H
10H
Intelligent Identifier
Read Status Register
Clear Status Register
Word/Byte Program
1
X
Read
Read
IA
X
IID
2,4
3
X
SRD
X
PA
PA
Write
Write
PA
PA
PD
PD
Alternate Word/Byte
Program
6,7
Block Erase/Confirm
Erase Suspend
6,7
5
Write
Write
Write
BA
X
20H
B0H
D0H
Write
BA
D0H
Erase Resume
X
ADDRESS
DATA
BA = Block Address
IA = Identifier Address
PA = Program Address
X = Don’t Care
SRD = Status Register Data
IID = Identifier Data
PD = Program Data
NOTES:
1. Bus operations are defined in Tables 3 and 4.
2. IA = Identifier Address: A0 = 0 for manufacturer code, A0 = 1 for device code.
3. SRD - Data read from Status Register.
4. IID = Intelligent Identifier Data. Following the Intelligent Identifier command, two read operations access manufacturer and
device codes.
5. BA = Address within the block being erased.
6. PA = Address to be programmed. PD = Data to be programmed at location PA.
7. Either 40H or 10H commands is valid.
8. When writing commands to the device, the upper data bus [DQ –DQ15] = X (28F400 only) which is either VIL or VIH, to
8
minimize current draw.
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4-MBIT SmartVoltage BOOT BLOCK FAMILY
E
Table 8. Status Register Bit Definition
WSMS
7
ESS
6
ES
5
DWS
4
VPPS
3
R
2
R
1
R
0
NOTES:
SR.7 =WRITE STATE MACHINE STATUS
Check Write State Machine bit first to determine
Word/Byte program or Block Erase completion,
before checking Program or Erase Status bits.
1 = Ready
0 = Busy
(WSMS)
SR.6 = ERASE-SUSPEND STATUS (ESS)
1 = Erase Suspended
When Erase Suspend is issued, WSM halts
execution and sets both WSMS and ESS bits to
“1.” ESS bit remains set to “1” until an Erase
Resume command is issued.
0 = Erase In Progress/Completed
SR.5 = ERASE STATUS (ES)
1 = Error In Block Erasure
0 = Successful Block Erase
When this bit is set to “1,” WSM has applied the
max number of erase pulses to the block and is
still unable to verify successful block erasure.
SR.4 = PROGRAM STATUS (DWS)
1 = Error in Byte/Word Program
0 = Successful Byte/Word Program
When this bit is set to “1,” WSM has attempted
but failed to program a byte or word.
SR.3 = VPP STATUS (VPPS)
The VPP Status bit does not provide continuous
indication of VPP level. The WSM interrogates VPP
level only after the Byte Write or Erase command
sequences have been entered, and informs the
system if VPP has not been switched on. The VPP
Status bit is not guaranteed to report accurate
1 = VPP Low Detect, Operation Abort
0 = VPP OK
feedback between VPPLK and VPPH
.
SR.2-SR.0 = RESERVED FOR FUTURE
ENHANCEMENTS (R)
These bits are reserved for future use and should
be masked out when polling the Status Register.
3.3.2
STATUS REGISTER
Important: The contents of the Status Register
are latched on the falling edge of OE# or CE#,
whichever occurs last in the read cycle. This
prevents possible bus errors which might occur if
Status Register contents change while being read.
CE# or OE# must be toggled with each subsequent
status read, or the Status Register will not indicate
completion of a program or erase operation.
The device Status Register indicates when
a
program or erase operation is complete, and the
success or failure of that operation. To read the
Status Register write the Read Status (70H)
command to the CUI. This causes all subsequent
read operations to output data from the Status
Register until another command is written to the
CUI. To return to reading from the array, issue a
Read Array (FFH) command.
When the WSM is active, the SR.7 register will
indicate the status of the WSM, and will also hold
the bits indicating whether or not the WSM was
successful in performing the desired operation.
The Status Register bits are output on DQ0–DQ7, in
both byte-wide (x8) or word-wide (x16) mode. In the
word-wide mode the upper byte, DQ8–DQ15
,
outputs 00H during a Read Status command. In the
byte-wide mode, DQ8–DQ14 are tri-stated and
DQ15/A–1 retains the low order address function.
20
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4-MBIT SmartVoltage BOOT BLOCK FAMILY
3.3.2.1
Clearing the Status Register
The Status Register should be cleared before
attempting the next operation. Any CUI instruction
can follow after programming is completed;
however, reads from the Memory Array or
Intelligent Identifier cannot be accomplished until
the CUI is given the appropriate command.
The WSM sets status bits 3 through 7 to “1,” and
clears bits 6 and 7 to “0,” but cannot clear status
bits 3 through 5 to “0.” Bits 3 through 5 can only be
cleared by the controlling CPU through the use of
the Clear Status Register (50H) command, because
these bits indicate various error conditions. By
allowing the system software to control the resetting
of these bits, several operations may be performed
(such as cumulatively programming several bytes
or erasing multiple blocks in sequence) before
reading the Status Register to determine if an error
occurred during that series. Clear the Status
Register before beginning another command or
3.3.4
ERASE MODE
To erase a block, write the Erase Set-Up and Erase
Confirm commands to the CUI, along with the
addresses identifying the block to be erased. These
addresses are latched internally when the Erase
Confirm command is issued. Block erasure results
in all bits within the block being set to “1.” Only one
block can be erased at a time.
sequence. Note, again, that
command must be issued before data can be read
from the memory or intelligent identifier.
a
Read Array
The WSM will execute a sequence of internally
timed events to:
3.3.3
PROGRAM MODE
1. Program all bits within the block to “0.”
Programming is executed using
a
two-write
2. Verify that all bits within the block are
sufficiently programmed to “0.”
sequence. The Program Setup command is written
to the CUI followed by a second write which
specifies the address and data to be programmed.
The WSM will execute a sequence of internally
timed events to:
3. Erase all bits within the block to “1.”
4. Verify that all bits within the block are
sufficiently erased.
1. Program the desired bits of the addressed
memory word or byte.
While the erase sequence is executing, bit 7 of the
Status Register is a “0.”
2. Verify that the desired bits are sufficiently
programmed.
When the Status Register indicates that erasure is
complete, check the Erase Status bit to verify that
the erase operation was successful. If the Erase
operation was unsuccessful, bit 5 of the Status
Register will be set to a “1,” indicating an Erase
Programming of the memory results in specific bits
within a byte or word being changed to a “0.”
If the user attempts to program “1”s, there will be no
change of the memory cell content and no error
occurs.
Failure. If V
PP was not within acceptable limits after
the Erase Confirm command is issued, the WSM
will not execute an erase sequence; instead, bit 5 of
the Status Register is set to a “1” to indicate an
Erase Failure, and bit 3 is set to a “1” to identify that
The Status Register indicates programming status:
while the program sequence is executing, bit 7 of
the Status Register is a “0.” The Status Register
can be polled by toggling either CE# or OE#. While
programming, the only valid command is Read
Status Register.
V
PP supply voltage was not within acceptable limits.
Clear the Status Register before attempting the
next operation. Any CUI instruction can follow after
erasure is completed; however, reads from the
Memory Array, Status Register, or Intelligent
Identifier cannot be accomplished until the CUI is
given the Read Array command.
When programming is complete, the Program
Status bits should be checked. If the programming
operation was unsuccessful, bit 4 of the Status
Register is set to a “1” to indicate a Program
Failure. If bit 3 is set to a “1,” then VPP was not
within acceptable limits, and the WSM did not
execute the programming sequence.
21
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4-MBIT SmartVoltage BOOT BLOCK FAMILY
3.3.4.1 Suspending and Resuming Erase
E
3.4.2
WP# = VIL FOR BOOT BLOCK
LOCKING
Since an erase operation requires on the order of
seconds to complete, an Erase Suspend command
is provided to allow erase-sequence interruption in
order to read data from another block of the
memory. Once the erase sequence is started,
writing the Erase Suspend command to the CUI
requests that the WSM pause the erase sequence
at a predetermined point in the erase algorithm. The
Status Register will indicate if/when the erase
operation has been suspended.
When WP# = VIL, the boot block is locked and any
program or erase operation to the boot block will
result in an error in the Status Register. All other
blocks remain unlocked in this condition and can be
programmed or erased normally. Note that this
feature is overridden and the boot block unlocked
when RP# = VHH
.
3.4.3
RP# = VHH OR WP# = VIH FOR BOOT
BLOCK UNLOCKING
At this point, a Read Array command can be written
to the CUI in order to read data from blocks other
than that which is being suspended. The only other
valid command at this time is the Erase Resume
command or Read Status Register command.
Two methods can be used to unlock the boot block:
1. WP# = VIH
2. RP# = VHH
During erase suspend mode, the chip can go into a
pseudo-standby mode by taking CE# to VIH, which
reduces active current draw.
If both or either of these two conditions are met, the
boot block will be unlocked and can be
programmed or erased.
To resume the erase operation, enable the chip by
taking CE# to VIL, then issuing the Erase Resume
command, which continues the erase sequence to
completion. As with the end of a standard erase
operation, the Status Register must be read,
cleared, and the next instruction issued in order to
continue.
3.4.4
UPGRADE NOTE FOR 8-MBIT
44-PSOP PACKAGE
If upgradability to 8M is required, note that the
8-Mbit in the 44-PSOP does not have a WP#
because no pins were available for the 8-Mbit
upgrade address. Thus, in this density-package
combination only, VHH (12V) on RP# is required to
unlock the boot block. Unlocking with a logic-level
signal is not possible. If this functionality is
required, and 12V is not available, consider using
the 48-TSOP package, which has a WP# pin and
can be unlocked with a logic-level signal. All other
density-package combinations have WP# pins.
3.4
Boot Block Locking
The boot block family architecture features
a
hardware-lockable boot block so that the kernel
code for the system can be kept secure while the
parameter and main blocks are programmed and
erased independently as necessary. Only the boot
block can be locked independently from the other
blocks. The truth table, Table 9, clearly defines the
write protection methods.
Table 9. Write Protection Truth Table
VPP
RP# WP#
Write Protection
Provided
VIL
X
X
X
All Blocks Locked
3.4.1
V
PP = VIL FOR COMPLETE
PROTECTION
≥ VPPLK
VIL
All Blocks Locked
(Reset)
For complete write protection of all blocks in the
flash device, the VPP programming voltage can be
held low. When VPP is below VPPLK, any program or
erase operation will result in a error in the Status
Register.
≥ VPPLK VHH
X
All Blocks Unlocked
≥ VPPLK
≥ VPPLK
VIH
VIH
VIL Boot Block Locked
VIH All Blocks Unlocked
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4-MBIT SmartVoltage BOOT BLOCK FAMILY
Start
Bus
Operation
Command
Comments
Write
Setup
Program
Data = 40H
Addr = Word/Byte to Program
Write 40H,
Word/Byte Address
Write
Read
Program
Data = Data to Program
Addr = Location to Program
Write Word/Byte
Data/Address
Status Register Data
Toggle CE# or OE#
to Update SRD.
Read
Status Register
Standby
Check SR.7
1 = WSM Ready
0 = WSM Busy
NO
SR.7 = 1
?
Repeat for subsequent word/byte program operations.
SR Full Status Check can be done after each word/byte program,
or after a sequence of word/byte programs.
YES
Write FFH after the last program operation to reset device to
read array mode.
Full Status
Check if Desired
Word/Byte Program
Complete
FULL STATUS CHECK PROCEDURE
Bus
Operation
Read Status Register
Data (See Above)
Command
Comments
Standby
Check SR.3
1
1 = VPP Low Detect
SR.3=
0
VPP Range Error
Standby
Check SR.4
1 = Word/Byte Program Error
1
Word/Byte Program
Error
SR.4 =
0
SR.3 MUST be cleared, if set during a program attempt,
before further attempts are allowed by the Write State Machine.
SR.4 is only cleared by the Clear Status Register command,
in cases where multiple bytes are programmed before full
status is checked.
Word/Byte Program
Successful
If error is detected, clear the Status Register before attempting
retry or other error recovery.
0530_09
Figure 9. Automated Word/Byte Programming Flowchart
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Start
Bus
Comments
Command
Operation
Data = 20H
Addr = Within Block to Be Erased
Write 20H,
Block Address
Write
Erase Setup
Erase
Confirm
Data = D0H
Addr = Within Block to Be Erased
Write
Read
Write D0H and
Block Address
Status Register Data Toggle CE#
or OE# to Update Status Register
Read Status
Register
Check SR.7
1 = WSM Ready
0 = WSM Busy
Suspend Erase
Loop
Standby
NO
0
YES
Suspend
Erase
SR.7 =
1
Repeat for subsequent block erasures.
Full Status Check can be done after each block erase, or after a
sequence of block erasures.
Write FFH after the last operation to reset device to read array mode.
Full Status
Check if Desired
Block Erase
Complete
FULL STATUS CHECK PROCEDURE
Bus
Operation
Read Status Register
Data (See Above)
Command
Comments
Check SR.3
1 = VPP Low Detect
Standby
1
SR.3 =
0
VPP Range Error
Check SR.4,5
Both 1 = Command Sequence Error
Standby
Standby
1
1
Command Sequence
Error
Check SR.5
1 = Block Erase Error
SR.4,5 =
0
SR.3 MUST be cleared, if set during an erase attempt, before further
attempts are allowed by the Write State Machine.
Block Erase Error
SR.5 =
0
SR.5 is only cleared by the Clear Status Register Command, in
cases where multiple blocks are erase before full status is checked.
If error is detected, clear the Status Register before attempting
retry or other error recovery.
Block Erase Successful
0530_10
Figure 10. Automated Block Erase Flowchart
24
PRELIMINARY
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4-MBIT SmartVoltage BOOT BLOCK FAMILY
Start
Bus
Operation
Command
Comments
Erase
Suspend
Data = B0H
Addr = X
Write
Read
Write B0H
Status Register Data Toggle CE#
or OE# to Update SRD
Addr = X
Read
Status Register
Check SR.7
1 = WSM Ready
0 = WSM Busy
Standby
Standby
0
0
SR.7 =
1
Check SR.6
1 = Erase Suspended
0 = Erase Completed
Data = FFH
Addr = X
Write
Read
Read Array
Erase Completed
CSR.6 =
Read array data from block other
than the one being erased.
1
Data = D0H
Addr = X
Write
Erase Resume
Write FFH
Read Array Data
NO
Done
Reading
YES
Write D0H
Write FFH
Erase Resumed
Read Array Data
0530_11
Figure 11. Erase Suspend/Resume Flowchart
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During erase or program modes, RP# low will abort
either erase or program operations, but the memory
contents are no longer valid as the data has been
corrupted by the RP# function. As in the read mode
above, all internal circuitry is turned off to achieve
the power savings.
3.5
Power Consumption
3.5.1
ACTIVE POWER
With CE# at a logic-low level and RP# at a logic-
high level, the device is placed in the active mode.
Refer to the DC Characteristics table for ICC current
values.
RP# transitions to VIL, or turning power off to the
device will clear the Status Register.
3.5.2
AUTOMATIC POWER SAVINGS (APS)
3.6
Power-Up/Down Operation
Automatic Power Savings (APS) provides low-
power operation during active mode. Power
Reduction Control (PRC) circuitry allows the device
to put itself into a low current state when not being
accessed. After data is read from the memory
array, PRC logic controls the device’s power
consumption by entering the APS mode where
typical ICC current is less than 1 mA. The device
stays in this static state with outputs valid until a
new location is read.
The device is protected against accidental block
erasure or programming during power transitions.
Power supply sequencing is not required, since the
device is indifferent as to which power supply, VPP
or VCC, powers-up first. The CUI is reset to the read
mode after power-up, but the system must drop
CE# low or present a new address to ensure valid
data at the outputs.
A system designer must guard against spurious
writes when VCC voltages are above VLKO and VPP
is active. Since both WE# and CE# must be low for
a command write, driving either signal to VIH will
inhibit writes to the device. The CUI architecture
provides additional protection since alteration of
memory contents can only occur after successful
completion of the two-step command sequences.
The device is also disabled until RP# is brought to
3.5.3
STANDBY POWER
With CE# at a logic-high level (VIH), and the CUI in
read mode, the memory is placed in standby mode,
which disables much of the device’s circuitry and
substantially reduces power consumption. Outputs
(DQ0–DQ15 or DQ0–DQ7) are placed in a high-
impedance state independent of the status of the
OE# signal. When CE# is at logic-high level during
erase or program operations, the device will
continue to perform the operation and consume
corresponding active power until the operation is
completed.
V
IH, regardless of the state of its control inputs. By
holding the device in reset (RP# connected to
system PowerGood) during power-up/down, invalid
bus conditions during power-up can be masked,
providing yet another level of memory protection.
3.6.1
RP# CONNECTED TO SYSTEM
RESET
3.5.4
DEEP POWER-DOWN MODE
The use of RP# during system reset is important
with automated write/erase devices because the
system expects to read from the flash memory
when it comes out of reset. If a CPU reset occurs
The SmartVoltage boot block family supports a low
typical ICC in deep power-down mode, which turns
off all circuits to save power. This mode is activated
by the RP# pin when it is at
a logic-low
without
a
flash memory reset, proper CPU
(GND ± 0.2V). Note: BYTE# pin must be at CMOS
initialization would not occur because the flash
memory may be providing status information
instead of array data. Intel’s Flash memories allow
proper CPU initialization following a system reset
by connecting the RP# pin to the same RESET#
signal that resets the system CPU.
levels to meet the ICCD specification.
During read modes, the RP# pin going low de-
selects the memory and places the output drivers in
a high impedance state. Recovery from the deep
power-down state, requires a minimum access time
of tPHQV (see AC Characteristics table).
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4-MBIT SmartVoltage BOOT BLOCK FAMILY
3.6.2
VCC, VPP AND RP# TRANSITIONS
Transient current magnitudes depend on the device
outputs’ capacitive and inductive loading. Two-line
control and proper decoupling capacitor selection
will suppress these transient voltage peaks. Each
The CUI latches commands as issued by system
software and is not altered by VPP or CE#
transitions or WSM actions. Its default state upon
power-up, after exit from deep power-down mode,
or after VCC transitions above VLKO (Lockout
voltage), is read array mode.
flash device should have
a 0.1 µF ceramic
capacitor connected between each VCC and GND,
and between its VPP and GND. These high-
frequency, inherently low-inductance capacitors
should be placed as close as possible to the
package leads.
After any word/byte write or block erase operation is
complete and even after VPP transitions down to
V
PPLK, the CUI must be reset to read array mode
3.7.1
V
PP TRACE ON PRINTED CIRCUIT
via the Read Array command if accesses to the
flash memory are desired.
BOARDS
Designing for in-system writes to the flash memory
requires special consideration of the VPP power
supply trace by the printed circuit board designer.
The VPP pin supplies the flash memory cells current
for programming and erasing. One should use
similar trace widths and layout considerations given
to the VCC power supply trace. Adequate VPP
supply traces, and decoupling capacitors placed
adjacent to the component, will decrease spikes
and overshoots.
Please refer to Intel’s application note AP-617
Additional Flash Data Protection Using VPP, RP#,
and WP#, for a circuit-level discription of how to
implement the protection discussed in Section 3.6.
3.7
Power Supply Decoupling
Flash memory’s power switching characteristics
require careful device decoupling methods. System
designers should consider three supply current
issues:
1. Standby current levels (ICCS
)
2. Active current levels (ICCR
)
3. Transient peaks produced by falling and rising
edges of CE#.
NOTE:
Table headings in Sections 5 and 6 (i.e., BV-60, BV-80, BV-120, TBV-80, TBE-120) refer to the
specific products listed below. See Appendix A for more information on product naming and line items.
Abbreviation
Applicable Product Names
BV-60
E28F004BV-T60, E28F004BV-B60, PA28F400BV-T60, PA28F400BV-B60,
E28F400CV-T60, E28F400CV-B60, E28F400BV-T60, E28F400BV-B60
BV-80
E28F004BV-T80, E28F004BV-B80, PA28F400BV-T80, PA28F400BV-B80,
E28F400CV-T80, E28F400CV-B80, E28F400BV-T80, E28F400BV-B80
BV-120
TBV-80
E28F004BV-T120, E28F004BV-B120, PA28F400BV-T120, PA28F400BV-B120
TE28F004BV-T80, TE28F004BV-B80, TB28F400BV-T80, TB28F400BV-B80,
TE28F400CV-T80, TE28F400CV-B80, TE28F400BV-T80, TE28F400BV-B80
TBE-120
TE28F004BE-T120, TE28F004BE-B120, TE28F400CE-T120, TE28F400CE-B120
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4.0 ABSOLUTE MAXIMUM
RATINGS*
NOTICE: This datasheet contains preliminary information on
new products in production. Do not finalize a design with
this information. Revised information will be published when
the product is available. Verify with your local Intel Sales
office that you have the latest datasheet before finalizing a
design.
Commercial Operating Temperature
During Read.................................0°C to +70°C
During Block Erase
and Word/Byte Program...............0°C to +70°C
* WARNING: Stressing the device beyond the "Absolute
Maximum Ratings" may cause permanent damage. These
are stress ratings only. Operation beyond the "Operating
Conditions" is not recommended and extended exposure
beyond the "Operating Conditions" may effect device
reliability.
Temperature Bias.....................–10°C to +80°C
Extended Operating Temperature
During Read.............................–40°C to +85°C
During Block Erase
and Word/Byte Program...........–40°C to +85°C
Temperature Under Bias ..........–40°C to +85°C
Storage Temperature....................–65°C to +125°C
Voltage on Any Pin
NOTES:
1. Operating temperature is for commercial product
defined by this specification.
2. Minimum DC voltage is –0.5V on input/output pins.
During transitions, this level may undershoot to–2.0V
for periods
(except VCC, VPP, A9 and RP#)
with Respect to GND..............–2.0V to +7.0V(2)
<20 ns. Maximum DC voltage on input/output pins is
Voltage on Pin RP# or Pin A9
V
V
CC + 0.5V which, during transitions, may overshoot to
CC + 2.0V for periods <20 ns.
with Respect to GND......... –2.0V to +13.5V(2,3)
3. Maximum DC voltage on VPP may overshoot to +14.0V
for periods <20 ns. Maximum DC voltage on RP# or A9
may overshoot to 13.5V for periods <20 ns.
VPP Program Voltage with Respect
to GND during Block Erase
and Word/Byte Program.... –2.0V to +14.0V(2,3)
4. Output shorted for no more than one second. No more
than one output shorted at a time.
VCC Supply Voltage
with Respect to GND..............–2.0V to +7.0V(2)
Output Short Circuit Current ...................100 mA (4)
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5.0 COMMERCIAL OPERATING CONDITIONS
Table 10. Commercial Temperature and VCC Operating Conditions
Symbol
Parameter
Notes
Min
0
Max
+70
3.6
Units
°C
TA
Operating Temperature
VCC
3.3V VCC Supply Voltage (± 0.3V)
5V VCC Supply Voltage (10%)
5V VCC Supply Voltage (5%)
3.0
Volts
Volts
Volts
1
2
4.50
4.75
5.50
5.25
NOTES:
1. 10% VCC specifications apply to the 60 ns, 80 ns and 120 ns product versions in their standard test configuration.
2. 5% VCC specifications apply to the 60 ns version in its high-speed test configuration.
required. If VCC ramps faster than 1V/100 µs (0.01
5.1
Applying V Voltages
CC
V/µs), then a delay of 2 µs is required before
initiating device operation. RP# GND is
=
When applying VCC voltage to the device, a delay
may be required before initiating device operation,
depending on the VCC ramp rate. If VCC ramps
slower than 1V/100 µs (0.01 V/µs) then no delay is
recommended during power-up to protect against
spurious write signals when VCC is between VLKO
and VCCMIN
.
VCC Ramp Rate
Required Timing
≤ 1V/100 µs
> 1V/100 µs
No delay required.
A delay time of 2 µs is required before any device operation is initiated, including read
operations, command writes, program operations, and erase operations. This delay is
measured beginning from the time VCC reaches VCCMIN (3.0V for 3.3 ± 0.3V operation;
and 4.5V for 5V operation).
NOTES:
1. These requirements must be strictly followed to guarantee all other read and write specifications.
2. To switch between 3.3V and 5V operation, the system should first transition VCC from the existing voltage range to GND,
and then to the new voltage. Any time the VCC supply drops below VCCMIN, the chip may be reset, aborting any operations
pending or in progress.
3. These guidelines must be followed for any VCC transition from GND.
29
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5.2
DC Characteristics
Table 11. DC Characteristics (Commercial)
Prod
BV-60
BV-80
BV-120
Sym
Parameter
VCC
3.3 ± 0.3V
5V ± 10%
Unit
Test Conditions
Note
Typ
Max
Typ
Max
VCC = VCC Max
VIN = VCC or GND
VCC = VCC Max
IIL
Input Load Current
1
1
± 1.0
± 10
1.5
± 1.0
± 10
2.0
µA
µA
ILO
ICCS
Output Leakage Current
VCC Standby Current
V
IN = VCC or GND
VCC = VCC Max
CE# = RP# = BYTE# =
WP# = VIH
1,3
0.4
60
0.8
50
mA
VCC = VCC Max
110
8
130
8
µA
µA
CE# = RP# = VCC
0.2V
±
VCC = VCC Max
ICCD
VCC Deep Power-Down
Current
1
0.2
15
0.2
50
V
IN = VCC or GND
RP# = GND ± 0.2V
VCC Read Current for
Word or Byte
CMOS INPUTS
VCC = VCC Max
CE# = GND, OE# = VCC
f = 10 MHz (5V)
5 MHz (3.3V)
ICCR
1,5,6
30
60
mA
IOUT = 0 mA, Inputs =
GND ± 0.2V or VCC
± 0.2V
TTL INPUTS
15
30
55
65
mA
VCC = VCC Max
CE# = VIL, OE# = VIH
f = 10 MHz (5V)
5 MHz (3.3V)
IOUT = 0 mA, Inputs =
VIL or VIH
VCC Program Current for
Word or Byte
VPP = VPPH1 (at 5V)
Program in Progress
VPP = VPPH2 (at 12V)
Program in Progress
VPP = VPPH1 (at 5V)
Block Erase in Progress
ICCW
1,4
1,4
13
10
13
10
30
25
30
25
30
30
18
18
50
45
35
30
mA
mA
mA
mA
ICCE
VCC Erase Current
VPP = VPPH2 (at 12V)
Block Erase in Progress
30
PRELIMINARY
E
4-MBIT SmartVoltage BOOT BLOCK FAMILY
Table 11. DC Characteristics (Commercial) (Continued)
Prod
BV-60
BV-80
BV-120
Sym
Parameter
VCC
3.3 ± 0.3V
5V ± 10%
Typ Max
10
Unit
Test Conditions
Note
Typ
Max
8.0
VCC Erase Suspend
Current
CE# = VIH
Block Erase Suspend
ICCES
1,2
3
5
mA
IPPS
VPP Standby Current
1
± 0.5 ± 15 ± 0.5 ± 10
µA
µA
VPP < VPPH
2
VPP Deep Power-Down
Current
IPPD
1
0.2
5.0
0.2
5.0
RP# = GND ± 0.2V
IPPR
IPPW
VPP Read Current
1
50
13
200
30
30
13
200
25
µA
VPP ≥ VPPH2
VPP = VPPH1 (at 5V)
Program in Progress
VPP Program Current for
Word or Byte
1,4
mA
VPP = VPPH2 (at 12V)
Program in Progress
VPP = VPPH1 (at 5V)
Block Erase in Progress
VPP = VPPH2 (at 12V)
Block Erase in Progress
8
13
8
25
30
8
10
5
20
20
IPPE
VPP Erase Current
1,4
1
mA
µA
25
15
VPP Erase
Suspend Current
V
PP = VPPH
IPPES
50
200
30
200
Block Erase Suspend in
Progress
IRP#
RP# Boot Block Unlock
Current
1,4
1,4
500
500
500
500
µA
µA
RP# = VHH
A9 Intelligent
Identifier Current
IID
A9 = VID
31
PRELIMINARY
4-MBIT SmartVoltage BOOT BLOCK FAMILY
E
Table 11. DC Characteristics (Commercial) (Continued)
Prod
BV-60
BV-80
BV-120
Sym
Parameter
VCC
3.3 ± 0.3V
5V ± 10%
Unit
Test Conditions
Note
Min
Max
Min
Max
VID
A9 Intelligent Identifier
Voltage
11.4
12.6
11.4
12.6
V
VIL
Input Low Voltage
–0.5
2.0
0.8
–0.5
2.0
0.8
V
V
VCC
+
VCC +
VIH
Input High Voltage
0.5V
0.5V
VCC = VCC Min
VOL
Output Low Voltage
0.45
0.45
V
V
V
V
I
OL = 5.8 mA
VCC = VCC Min
OH = –2.5 mA
VCC = VCC Min
OH = –2.5 mA
CC = VCC Min
OH = –100 µA
VOH
1
2
Output High Voltage (TTL)
Output High Voltage (CMOS)
2.4
2.4
I
0.85 ×
VCC
0.85 ×
VCC
VOH
I
V
VCC–
0.4V
VCC–
0.4V
I
VPPLK VPP Lock-Out Voltage
3
8
0.0
4.5
1.5
5.5
0.0
4.5
1.5
5.5
V
V
V
V
V
Total Write Protect
VPP at 5V
VPPH
1
2
VPP (Prog/Erase Operations)
VPP (Prog/Erase Operations)
VPPH
11.4
2.0
12.6
11.4
2.0
12.6
VPP at 12V
VLKO VCC Erase/Prog Lock Voltage
VHH RP# Unlock Voltage
11.4
12.6
11.4
12.6
Boot Block Unlock
Table 12. Capacitance (TA = 25°C, f = 1 MHz)
Symbol
CIN
Parameter
Note
4
Typ
6
Max
8
Unit
pF
Conditions
VIN = 0V
Input Capacitance
Output Capacitance
COUT
4, 7
10
12
pF
VOUT = 0V
NOTES:
1. All currents are in RMS unless otherwise noted. Typical values at VCC = 5.0V, T = +25°C. These currents are valid for all
product versions (packages and speeds).
2.
I
I
CCES is specified with the device deselected. If the device is read while in erase suspend mode, current draw is the sum of
CCES and ICCR
.
3. Block erases and word/byte writes are inhibited when VPP = VPPLK, and not guaranteed in the range between VPPH1 and
VPPLK
.
4. Sampled, not 100% tested.
5. Automatic Power Savings (APS) reduces ICCR to less than 1 mA typical, in static operation.
6. CMOS Inputs are either VCC ± 0.2V or GND ± 0.2V. TTL Inputs are either VIL or VIH
7. For the 28F004B, address pin A10 follows the COUT capacitance numbers.
8. For all BV/CV parts, VLKO = 2.0V for both 3.3V and 5V operations.
.
32
PRELIMINARY
E
4-MBIT SmartVoltage BOOT BLOCK FAMILY
3.0
OUTPUT
INPUT
1.5
TEST POINTS
1.5
0.0
NOTE:
AC test inputs are driven at 3.0V for a logic “1” and 0.0V for a logic “0.” Input timing begins, and output timing ends, at 1.5V.
Input rise and fall times (10% to 90%) <10 ns.
0530_12
Figure 12. 3.3V Inputs and Measurement Points
2.4
2.0
2.0
0.8
INPUT
OUTPUT
TEST POINTS
0.8
0.45
NOTE:
AC test inputs are driven at VOH (2.4 VTTL) for a logic “1” and VOL (0.45 VTTL) for a logic “0.” Input timing begins at VIH (2.0 VTTL
and VIL (0.8 VTTL) . Output timing ends at VIH and VIL. Input rise and fall times (10% to 90%) <10 ns.
)
0530_13
Figure 13. 5V Inputs and Measurement Points
Test Configuration Component Values
VCC
Test Configuration
CL (pF) R1 (Ω) R2 (Ω)
R
R
3.3V Standard Test
5V Standard Test
5V High-Speed Test
50
100
30
990
580
580
770
390
390
1
DEVICE
UNDER
TEST
OUT
NOTE: CL includes jig capacitance.
C
L
2
0530_14
NOTE: See table for component values.
Figure 14. Test Configuration
33
PRELIMINARY
4-MBIT SmartVoltage BOOT BLOCK FAMILY
E
Unit
5.3
AC Characteristics
Table 13. AC Characteristics: Read Only Operations (Commercial)
Prod
VCC
BV-60
5V ± 5%(6)
30 pF
Sym
Parameter
3.3 ± 0.3V(5)
50 pF
5V ± 10%(7)
100 pF
Load
Note
Min
Max
Min
Max
Min
Max
tAVAV Read Cycle Time
110
60
70
ns
ns
ns
µs
ns
ns
ns
ns
ns
ns
tAVQV Address to Output Delay
tELQV CE# to Output Delay
tPHQV RP# to Output Delay
tGLQV OE# to Output Delay
tELQX CE# to Output in Low Z
tEHQZ CE# to Output in High Z
tGLQX OE# to Output in Low Z
tGHQZ OE# to Output in High Z
110
110
0.8
65
60
60
70
70
2
0.45
30
0.45
35
2
3
3
3
3
3
0
0
0
0
0
0
0
0
0
25
25
20
20
20
20
tOH
Output Hold from Address,
CE#, or OE# Change,
Whichever Occurs First
tELFL
tELFH
CE# Low to BYTE# High or
Low
3
3
0
0
0
ns
ns
tAVFL Address to BYTE# High or
Low
5
5
5
tFLQV
tFHQV
BYTE# to Output Delay
3,4
3
110
45
60
20
70
25
ns
ns
tFLQZ BYTE# Low to Output in
High Z
tPLPH Reset Pulse Width Low
tPLQZ RP# Low to Output High Z
8
150
60
60
ns
ns
150
60
60
34
PRELIMINARY
E
4-MBIT SmartVoltage BOOT BLOCK FAMILY
Table 13. AC Characteristics: Read Only Operations (Commercial) (Continued)
BV-80 BV-120
VCC 3.3 ± 0.3V(5) 5V ± 10%(7) 3.3 ± 0.3V(5) 5V ± 10%(7) Unit
Load 50 pF 100 pF 50 pF 100 pF
Notes Min Max Min Max Min Max Min Max
Sym
Parameter
tAVAV Read Cycle Time
150
80
180
120
ns
ns
ns
tAVQV Address to Output Delay
tELQV CE# to Output Delay
tPHQV RP# to Output Delay
tGLQV OE# to Output Delay
tELQX CE# to Output in Low Z
tEHQZ CE# to Output in High Z
tGLQX OE# to Output in Low Z
tGHQZ OE# to Output in High Z
150
150
0.8
90
80
80
180
180
0.8
90
120
120
2
0.45
40
0.45 µs
2
3
3
3
3
3
40
20
20
ns
ns
ns
ns
ns
ns
0
0
0
0
0
0
0
0
0
0
0
0
25
25
20
20
25
25
tOH
Output Hold from Address,
CE#, or OE# Change,
Whichever Occurs First
tELFL
tELFH
CE# Low to BYTE# High or
Low
3
3
0
0
0
0
ns
ns
tAVFL Address to BYTE# High or
Low
5
5
5
5
tFLQV
tFHQV
BYTE# to Output Delay
3,4
3
150
60
80
30
180
60
120
30
ns
ns
tFLQZ BYTE# Low to Output in
High Z
tPLPH Reset Pulse Width Low
8
150
60
150
60
ns
tPLQZ RP# Low to Output High Z
150
60
150
60
NOTES:
1. See AC Input/Output Reference Waveform for timing measurements.
2. OE# may be delayed up to tCE–tOE after the falling edge of CE# without impact on tCE
.
3. Sampled, but not 100% tested.
4.
tFLQV, BYTE# switching low to valid output delay will be equal to tAVQV, measured from the time DQ15/A–1 becomes valid.
5. See Test Configurations (Figure 14), 3.3V Standard Test component values.
6. See Test Configurations (Figure 14), 5V High-Speed Test component values.
7. See Test Configurations (Figure 14), 5V Standard Test component values.
8. The specification tPLPH is the minimum time RP# must be held low to produce a valid reset of the device.
35
PRELIMINARY
4-MBIT SmartVoltage BOOT BLOCK FAMILY
E
Device and
Data
Valid
Standby
Address Selection
V
IH
ADDRESSES (A)
Address Stable
VIL
tAVAV
V
IH
CE# (E)
V
IL
tEHQZ
V
IH
OE# (G)
V
IL
tGHQZ
V
WE# (W) IH
tGLQV
tGLQX
tOH
VIL
tELQV
VOH
DATA (D/Q)
VOL
tELQX
High Z
High Z
Valid Output
tAVQV
V
IH
RP#(P)
VIL
tPHQV
0530_15
Figure 15. AC Waveforms for Read Operations
Device
Address Selection
Data
Valid
Standby
VIH
ADDRESSES (A)
VIL
Address Stable
tAVAV
VIH
CE# (E)
VIL
tEHQZ
tAVFL
VIH
OE# (G)
tELFL
VIL
tGHQZ
VIH
BYTE# (F)
VIL
tGLQV
tELQV
tGLQX
tOH
VOH
tELQX
High Z
High Z
High Z
High Z
High Z
DATA (D/Q)
(DQ0-DQ7)
VOL
Data Output
on DQ0-DQ7
Data Output
on DQ0-DQ7
tAVQV
VOH
DATA (D/Q)
(DQ8-DQ14)
VOL
Data Output
on DQ8-DQ14
t FLQZ
tAVQV
VOH
(DQ15/A-1)
VOL
High Z
Data Output
on DQ15
Address Input
0530_16
Figure 16. BYTE# Timing Diagram for Read Operations
36
PRELIMINARY
E
4-MBIT SmartVoltage BOOT BLOCK FAMILY
Table 14. AC Characteristics: WE#–Controlled Write Operations (1) (Commercial)
Prod
VCC
BV-60
5V ± 5%(10)
30 pF
Sym
Parameter
3.3 ± 0.3V(9)
50 pF
5V ± 10%(10) Unit
100 pF
Load
Note
Min
110
0.8
0
Max
Min
60
Max
Min
70
Max
tAVAV
tPHWL
tELWL
Write Cycle Time
ns
µs
ns
ns
RP# Setup to WE# Going Low
CE# Setup to WE# Going Low
0.45
0
0.45
0
tPHHWH Boot Block Lock Setup to WE#
Going High
6,8
200
100
100
VPP Setup to WE# Going High
tVPWH
5,8
3
200
90
100
50
100
50
ns
ns
tAVWH
Address Setup to WE# Going
High
tDVWH
tWLWH
tWHDX
tWHAX
Data Setup to WE# Going High
WE# Pulse Width
4
90
90
0
50
50
0
50
50
0
ns
ns
ns
ns
Data Hold Time from WE# High
4
3
Address Hold Time from WE#
High
0
0
0
tWHEH
tWHWL
CE# Hold Time from WE# High
WE# Pulse Width High
0
20
6
0
10
6
0
20
6
ns
ns
µs
s
tWHQV1 Duration of Word/Byte Program
tWHQV2 Duration of Erase (Boot)
tWHQV3 Duration of Erase (Parameter)
tWHQV4 Duration of Erase (Main)
2,5
2,5,6
2,5
0.3
0.3
0.6
0
0.3
0.3
0.6
0
0.3
0.3
0.6
0
s
2,5
s
tQVVL
tQVPH
tPHBR
VPP Hold from Valid SRD
RP# VHH Hold from Valid SRD
Boot-Block Lock Delay
5,8
ns
ns
ns
6,8
0
0
0
7,8
200
100
100
37
PRELIMINARY
4-MBIT SmartVoltage BOOT BLOCK FAMILY
E
Table 14. AC Characteristics: WE#–Controlled Write Operations (1) (Commercial) (Continued)
Prod BV-80 BV-120
VCC 3.3 ±0.3V (9) 5V±10%(11) 3.3 ± 0.3V(9) 5V±10%(11) Unit
Load 50 pF 100 pF 50 pF 100 pF
Sym
Parameter
Notes Min
Max
Min
Max
Min
Max
Min
Max
tAVAV
tPHWL
Write Cycle Time
150
0.8
80
180
0.8
120
ns
RP# Setup to WE# Going
Low
0.45
0.45
µs
tELWL
CE# Setup to WE# Going
Low
0
0
0
0
ns
ns
tPHHWH Boot Block Lock Setup to
WE# Going High
6,8
200
100
200
100
VPP Setup to WE# Going
tVPWH
5,8
3
200
120
100
50
200
150
100
50
ns
ns
High
tAVWH
tDVWH
Address Setup to WE#
Going High
Data Setup to WE# Going
High
4
120
50
150
50
ns
tWLWH
tWHDX
WE# Pulse Width
120
0
50
0
150
0
50
0
ns
ns
Data Hold Time from
WE# High
4
3
tWHAX
tWHEH
tWHWL
Address Hold Time from
WE# High
0
0
0
0
0
0
0
0
ns
ns
CE# Hold Time from WE#
High
WE# Pulse Width High
30
6
30
6
30
6
30
6
ns
µs
s
tWHQV1 Word/Byte Program Time
tWHQV2 Erase Duration (Boot)
tWHQV3 Erase Duration (Param)
tWHQV4 Erase Duration (Main)
2,5
2,5,6
2,5
0.3
0.3
0.6
0
0.3
0.3
0.6
0
0.3
0.3
0.6
0
0.3
0.3
0.6
0
s
2,5
s
tQVVL
tQVPH
VPP Hold from Valid SRD
5,8
ns
ns
RP# VHH Hold from Valid
SRD
6,8
0
0
0
0
tPHBR
Boot-Block Lock Delay
7,8
200
100
200
100
ns
38
PRELIMINARY
E
4-MBIT SmartVoltage BOOT BLOCK FAMILY
NOTES:
1. Read timing characteristics during write and erase operations are the same as during read-only operations. Refer to AC
characteristics during read mode.
2. The on-chip WSM completely automates program/erase operations; program/erase algorithms are now controlled internally
which includes verify and margining operations.
3. Refer to command definition table for valid A . (Table 7)
IN
4. Refer to command definition table for valid D . (Table 7)
IN
5. Program/erase durations are measured to valid SRD data (successful operation, SR.7 = 1).
6. For boot block program/erase, RP# should be held at VHH or WP# should be held at VIH until operation completes
successfully.
7. Time tPHBR is required for successful locking of the boot block.
8. Sampled, but not 100% tested.
9. See Test Configurations (Figure 14), 3.3V Standard Test component values.
10. See Test Configurations (Figure 14), 5V High-Speed Test component values.
11. See Test Configurations (Figure 14), 5V Standard Test component values.
1
2
3
4
5
6
V
IH
ADDRESSES (A)
A
A
IN
IN
V
IL
tAVAV
tAVWH
tWHAX
V
IH
CE# (E)
VIL
tELWL
tWHEH
V
IH
OE# (G)
VIL
tWHWL
tWHQV1,2,3,4
V
IH
WE# (W)
V
IL
tWLWH
tDVWH
tWHDX
V
IH
High Z
Valid
SRD
DATA (D/Q)
D
D
IN
D
IN
IN
V
IL
tPHHWH
tPHWL
tQVPH
6.5V VHH
V
IH
RP# (P)
VIL
V
IH
WP#
VIL
tQVVL
tVPWH
VPPH2
VPPH
VPPLK
VIL
1
V
(V)
PP
0530_17
NOTES:
1. V Power-Up and Standby.
CC
2. Write Program or Erase Setup Command.
3. Write Valid Address and Data (Program) or Erase Confirm Command.
4. Automated Program or Erase Delay.
5. Read Status Register Data.
6. Write Read Array Command.
Figure 17. AC Waveforms for Write Operations (WE#–Controlled Writes)
39
PRELIMINARY
4-MBIT SmartVoltage BOOT BLOCK FAMILY
E
Table 15. AC Characteristics: CE#–Controlled Write Operations (1,12) (Commercial)
Prod
VCC
BV-60
5V ± 5%(10)
30 pF
Sym
Parameter
3.3 ± 0.3V(9)
50 pF
5V ± 10%(11) Unit
100 pF
Load
Note
Min
110
0.8
Max
Min
60
Max
Min
70
Max
tAVAV
Write Cycle Time
ns
µs
tPHEL
RP# High Recovery to CE#
Going Low
0.45
0.45
tWLEL
WE# Setup to CE# Going Low
0
0
0
ns
ns
tPHHEH Boot Block Lock Setup to CE#
Going High
6,8
200
100
100
VPP Setup to CE# Going High
tVPEH
tAVEH
5,8
3
200
90
100
50
100
50
ns
ns
Address Setup to CE# Going
High
tDVEH
tELEH
tEHDX
tEHAX
Data Setup to CE# Going High
CE# Pulse Width
4
90
90
0
50
50
0
50
50
0
ns
ns
ns
ns
Data Hold Time from CE# High
4
3
Address Hold Time from CE#
High
0
0
0
tEHWH
tEHEL
WE # Hold Time from CE# High
CE# Pulse Width High
0
20
6
0
10
6
0
20
6
ns
ns
µs
tEHQV1
Duration of Word/Byte
Programming Operation
2,5
Erase Duration (Boot)
Erase Duration (Param)
Erase Duration(Main)
VPP Hold from Valid SRD
tEHQV2
tEHQV3
tEHQV4
tQVVL
2,5,6
2,5
0.3
0.3
0.6
0
0.3
0.3
0.6
0
0.3
0.3
0.6
0
s
s
2,5
s
5,8
ns
ns
RP# VHH Hold from
Valid SRD
tQVPH
6,8
0
0
0
tPHBR
Boot-Block Lock Delay
7,8
200
100
100
ns
40
PRELIMINARY
E
4-MBIT SmartVoltage BOOT BLOCK FAMILY
Table 15. AC Characteristics: CE#–Controlled Write Operations (1,12) (Commercial) (Continued)
Prod BV-80 BV-120
VCC 3.3 ± 0.3V(9) 5V±10%(11) 3.3 ± 0.3V(9) 5V±10%(11) Unit
Load 50 pF 100 pF 50 pF 100 pF
Notes Min Max Min Max Min Max Min Max
Sym
Parameter
150
0.8
80
180
0.8
120
ns
tAVAV
tPHEL
Write Cycle Time
0.45
0.45
µs
RP# High Recovery to
CE# Going Low
0
0
0
0
ns
ns
tWLEL
WE# Setup to CE# Going
Low
6,8
200
100
200
100
tPHHEH Boot Block Lock Setup to
CE# Going High
VPP Setup to CE# Going
tVPEH
5,8
3
200
120
100
50
200
150
100
50
ns
ns
High
tAVEH
Address Setup to CE#
Going High
4
120
50
150
50
ns
tDVEH
Data Setup to CE# Going
High
120
0
50
0
150
0
50
0
ns
ns
tELEH
tEHDX
CE# Pulse Width
4
3
Data Hold Time from CE#
High
0
0
0
0
0
0
0
0
ns
ns
tEHAX
Address Hold Time from
CE# High
tEHWH
WE # Hold Time from
CE# High
30
6
30
6
30
6
30
6
ns
tEHEL
CE# Pulse Width High
2,5
µs
tEHQV1
Duration of Word/Byte
Programming Operation
Erase Duration (Boot)
Erase Duration (Param)
Erase Duration(Main)
VPP Hold from Valid SRD
2,5,6
2,5
0.3
0.3
0.6
0
0.3
0.3
0.6
0
0.3
0.3
0.6
0
0.3
0.3
0.6
0
s
s
tEHQV2
tEHQV3
tEHQV4
tQVVL
2,5
s
5,8
ns
ns
RP# VHH Hold from
Valid SRD
6,8
0
0
0
0
tQVPH
7,8
200
100
200
100
ns
tPHBR
Boot-Block Lock Delay
41
PRELIMINARY
4-MBIT SmartVoltage BOOT BLOCK FAMILY
E
NOTES:
See WE# Controlled Write Operations for notes 1 through 11.
12. Chip-Enable controlled writes: write operations are driven by the valid combination of CE# and WE# in systems where
CE# defines the write pulse-width (within a longer WE# timing waveform), all set-up, hold and inactive WE# times should
be measured relative to the CE# waveform.
1
2
3
4
5
6
VIH
ADDRESSES (A)
VIL
AIN
AIN
tAVAV
tAVEH
tEHAX
VIH
WE# (W)
VIL
tWLEL
tEHWH
VIH
OE# (G)
VIL
VIH
t EHEL
t EHQV1,2,3,4
CE# (E)
VIL
t ELEH
t DVEH
t EHDX
VIH
DATA (D/Q)
VIL
High Z
t PHEL
Valid
SRD
D
D
D
IN
IN
IN
tPHHEH
tQVPH
VHH
6.5V
VIH
RP# (P)
VIL
VIH
WP#
VIL
t VPEH
tQVVL
VPPH2
VPPH
VPPLK
VIL
1
VPP(V)
0530_18
NOTES:
1. V Power-Up and Standby.
CC
2. Write Program or Erase Setup Command.
3. Write Valid Address and Data (Program) or Erase Confirm Command.
4. Automated Program or Erase Delay.
5. Read Status Register Data.
6. Write Read Array Command.
Figure 18. Alternate AC Waveforms for Write Operations (CE#–Controlled Writes)
42
PRELIMINARY
E
4-MBIT SmartVoltage BOOT BLOCK FAMILY
Table 16. Erase and Program Timings (Commercial TA = 0°C to +70°C)
5V ± 10%
3.3 ± 0.3V
12V ± 5%
3.3 ± 0.3V 5V ± 10%
Typ Max Unit
VPP
5V ± 10%
Typ Max
VCC
Parameter
Typ
0.84
2.4
1.7
1.1
10
Max
Typ
0.44
1.3
1.6
0.8
8
Max
Boot/Parameter Block Erase Time
Main Block Erase Time
7
0.8
1.9
1.8
0.9
10
7
7
0.34
1.1
1.2
0.6
8
7
s
s
14
14
14
14
Main Block Program Time (Byte)
Main Block Program Time (Word)
Byte Program Time(4)
s
s
µs
µs
Word Program Time(4)
13
13
8
8
NOTES:
1. All numbers are sampled, not 100% tested.
2. Max erase times are specified under worst case conditions. The max erase times are tested at the same value
independent of VCC and VPP. See Note 3 for typical conditions.
3. Typical conditions are +25°C with VCC and VPP at the center of the specifed voltage range. Production programming using
CC = 5.0V, VPP = 12.0V typically results in a 60% reduction in programming time.
V
4. Contact your Intel field representative for more information.
43
PRELIMINARY
4-MBIT SmartVoltage BOOT BLOCK FAMILY
E
6.0 EXTENDED OPERATING CONDITIONS
Table 17. Extended Temperature and VCC Operating Conditions
Symbol
TA
Parameter
Notes
Min
–40
2.7
Max
+85
3.6
Units
°C
Operating Temperature
VCC
2.7V–3.6V VCC Supply Voltage
3.3V VCC Supply Voltage (± 0.3V)
5V VCC Supply Voltage (10%)
1
1
2
Volts
Volts
Volts
3.0
3.6
4.50
5.50
NOTES:
1. AC specifications are valid at both voltage ranges. See DC Characteristics tables for voltage range-specific specifications.
2. 10% VCC specifications apply to 80 ns and 120 ns versions in their standard test configuration.
required. If VCC ramps faster than 1V/100 µs (0.01
6.1
Applying V Voltages
CC
V/µs), then a delay of 2 µs is required before
initiating device operation. RP# GND is
=
When applying VCC voltage to the device, a delay
may be required before initiating device operation,
depending on the VCC ramp rate. If VCC ramps
slower than 1V/100 µs (0.01 V/µs) then no delay is
recommended during power-up to protect against
spurious write signals when VCC is between VLKO
and VCCMIN
.
VCC Ramp Rate
Required Timing
≤ 1V/100 µs
> 1V/100 µs
No delay required.
A delay time of 2 µs is required before any device operation is initiated, including read
operations, command writes, program operations, and erase operations. This delay is
measured beginning from the time VCC reaches VCCMIN (2.7V for 2.7V–3.6V operation,
3.0V for 3.3 ± 0.3V operation; and 4.5V for 5V operation).
NOTES:
1. These requirements must be strictly followed to guarantee all other read and write specifications.
2. To switch between 3.3V and 5V operation, the system should first transition VCC from the existing voltage range to GND,
and then to the new voltage. Any time the VCC supply drops below VCCMIN, the chip may be reset, aborting any operations
pending or in progress.
3. These guidelines must be followed for any VCC transition from GND.
44
PRELIMINARY
E
4-MBIT SmartVoltage BOOT BLOCK FAMILY
6.2
DC Characteristics
Table 18. DC Characteristics: Extended Temperature Operation
Prod
TBE-120
TBV-80
TBV-80
TBE-120
Sym Parameter
VCC
2.7V–3.6V
3.3 ± 0.3V
5V ± 10%
Unit
Test Conditions
Notes Typ Max Typ Max Typ Max
VCC = VCCMax
IIL
Input Load
Current
1
± 1.0
± 1.0
± 1.0
µA
µA
V
IN = VCC or GND
VCC = VCC Max
IN = VCC or GND
ILO
Output
Leakage
Current
1
± 10
± 10
± 10
V
VCC
CMOS Levels
VCC = VCC Max
ICCS
1,3
50
110
1.5
60
110
1.5
70
150
2.5
µA
Standby
Current
CE# = RP# = WP# =
VCC ± 0.2V
TTL Levels
0.4
0.4
0.8
mA
V
CC = VCC Max
CE# = RP# = BYTE#
= VIH
VCC Deep
Power-
Down
VCC = VCC Max
ICCD
1
0.2
14
8
0.2
15
8
0.2
50
8
µA
V
IN = VCC or GND
RP# = GND ± 0.2V
Current
VCC Read
Current for
Word or
Byte
CMOS INPUTS
VCC = VCC Max
CE = VIL
ICCR
1,5,6
30
30
65
mA
f = 10 MHz (5V)
5 MHz (3.3V)
IOUT = 0 mA
Inputs = GND ± 0.2V
or VCC ± 0.2V
TTL INPUTS
VCC = VCC Max
CE# = VIL
14
30
15
30
55
70
mA
f = 10 MHz (5V),
5 MHz (3.3V)
IOUT = 0 mA
Inputs = VIL or VIH
45
PRELIMINARY
4-MBIT SmartVoltage BOOT BLOCK FAMILY
E
Test Conditions
Table 18. DC Characteristics: Extended Temperature Operation (Continued)
Prod
TBE-120
TBV-80
TBV-80
TBE-120
Sym Parameter
VCC
2.7V–3.6V
3.3 ± 0.3V
5V ± 10%
Unit
Notes Typ Max Typ Max
Typ Max
VCC
Program
Current
VPP = VPPH1 (at 5V)
Program in Progress
ICCW
1,4
8
30
13
30
30
50
mA
mA
V
PP = VPPH2 (at 12V)
for Word or
Byte
9
25
10
25
30
45
Program in Progress
VCC Erase
ICCE
V
PP = VPPH1 (at 5V)
1,4
12
9
30
25
13
10
3
30
25
22
18
5
45
40
mA
mA
mA
Erase in Progress
Current
V
PP = VPPH2 (at 12V)
Erase in Progress
VCC Erase
ICCES
CE# = VIH
VPP = VPPH1 (at 5V)
1,2
1
2.5
8.0
8.0
12.0
Suspend
Current
Block Erase Suspend
VPP
IPPS
± 5
0.2
± 15
10
± 5
0.2
± 15
10
± 5
0.2
± 15
10
µA VPP < VPPH2
Standby
Current
VPP Deep
IPPD
1
µA RP# = GND ± 0.2V
Power-
Down
Current
VPP Read
IPPR
1
50
13
8
200
30
50
13
8
200
30
50
13
8
200
30
µA VPP ≥ VPPH2
Current
VPP
Program
VPP = VPPH1 (at 5V)
Program in Progress
IPPW
1,4
mA
mA
Current for
Word/Byte
V
PP = VPPH2 (at 12V)
25
25
25
Program in Progress
46
PRELIMINARY
E
4-MBIT SmartVoltage BOOT BLOCK FAMILY
Table 18. DC Characteristics: Extended Temperature Operation (Continued)
Prod
TBE-120
TBV-80
TBV-80
TBE-120
Sym Parameter
VCC
2.7V–3.6V
3.3 ± 0.3V
5V ± 10%
Unit
Test Conditions
Notes Typ Max Typ Max
Typ Max
V
PP = VPPH1 (at 5V)
VPP Erase
IPPE
1,4
13
30
13
30
15
10
50
25
mA
mA
µA
Block Erase in
Progress
Current
VPP = VPPH2 (at 12V)
Block Erase in
Progress
8
25
8
25
20
VPP = VPPH
Block Erase Suspend
in Progress
VPP Erase
IPPES
1
50
200
50
200
200
Suspend
Current
RP# = VHH
VPP = 12V
IRP#
RP# Boot
Block
Unlock
Current
1,4
500
500
500
500
500
500
µA
A9
IID
1,4
µA A9 = VID
Intelligent
Identifier
Current
47
PRELIMINARY
4-MBIT SmartVoltage BOOT BLOCK FAMILY
E
Table 18. DC Characteristics: Extended Temperature Operation (Continued)
Prod
TBE-120
TBV-80
TBV-80
TBE-120
Sym Parameter
VCC
2.7V–3.6V
3.3 ± 0.3V
5V ± 10%
Unit
Test Conditions
Notes Min Max
Min
Max Min Max
A9
VID
11.4 12.6 11.4
12.6 11.4 12.6
V
Intelligent
Identifier
Voltage
VIL
Input Low
Voltage
–0.5
2.0
0.8
–0.5
2.0
0.8
–0.5
2.0
0.8
V
V
VCC
±
0.5V
VCC
±
0.5V
VCC
±
0.5V
VIH
Input High
Voltage
VCC = VCC Min
IOL = 5.8 mA (5V)
2 mA (3.3V)
VOL
Output Low
Voltage
0.45
0.45
0.45
V
V
VPP = 12V
VCC = VCC Min
IOH = –2.5 mA
VOH
1
Output
High
2.4
2.4
2.4
Voltage
(TTL)
VCC = VCC Min
IOH = –2.5 mA
VOH2
Output
High
0.85
×
0.85
×
0.85
×
V
Voltage
VCC
VCC
VCC
VCC = VCC Min
IOH = –100 µA
(CMOS)
VCC–
0.4V
0.0
VCC–
0.4V
0.0
VCC–
0.4V
0.0
V
V
V
VPP
VPPLK
3
8
1.5
5.5
1.5
5.5
1.5
5.5
Complete Write
Protection
Lock-Out
Voltage
VPP during
Prog/Erase
Operations
VPPH1
4.5
4.5
4.5
V
PP at 5V
VPPH2
11.4 12.6 11.4
2.0 2.0
12.6 11.4 12.6
2.0
V
V
VPP at 12V
VCC
VLKO
Erase/Write
Lock
Voltage
VPP = 12V
VHH
RP#
11.4 12.6 11.4
12.6 11.4 12.6
V
Boot Block Write/
Erase
Unlock
Voltage
48
PRELIMINARY
E
4-MBIT SmartVoltage BOOT BLOCK FAMILY
Table 19. Capacitance (TA = 25 °C, f = 1 MHz)
Symbol
Parameter
Note
Typ
6
Max
8
Unit
pF
Conditions
VIN = 0V
VOUT = 0V
CIN
Input Capacitance
Output Capacitance
4
4
COUT
10
12
pF
NOTES:
1. All currents are in RMS unless otherwise noted. Typical values at VCC = 5.0V, T = +25°C. These currents are valid for all
product versions (packages and speeds).
2.
3. Block erases and word/byte programs inhibited when VPP = VPPLK, and not guaranteed in the range between VPPH1 and
VPPLK
I
CCES is specified with device de-selected. If device is read while in erase suspend, current draw is sum of ICCES and ICCR
.
.
4. Sampled, not 100% tested.
5. Automatic Power Savings (APS) reduces ICCR to less than 1 mA typical, in static operation.
6. CMOS Inputs are either VCC ± 0.2V or GND ± 0.2V. TTL Inputs are either VIL or VIH
7. For the 28F004B address pin A10 follows the COUT capacitance numbers.
8. For all BV/CV/BE/CE parts, VLKO = 2.0V for 2.7V, 3.3V and 5.0V operations.
.
49
PRELIMINARY
4-MBIT SmartVoltage BOOT BLOCK FAMILY
E
2.7
OUTPUT
INPUT
1.35
TEST POINTS
1.35
0.0
0530_19
NOTE:
AC test inputs are driven at 2.7V for a logic “1” and 0.0V for a logic “0.” Input timing begins, and output timing ends, at 1.35V.
Input rise and fall times (10% to 90%) <10 ns.
Figure 19. 2.7V–3.6V Input Range and Measurement Points
3.0
OUTPUT
INPUT
1.5
TEST POINTS
1.5
0.0
0530_12
NOTE:
AC test inputs are driven at 3.0V for a logic “1” and 0.0V for a logic “0.” Input timing begins, and output timing ends, at 1.5V.
Input rise and fall times (10% to 90%) <10 ns.
Figure 20. 3.3V Input Range and Measurement Points
2.4
2.0
0.8
2.0
0.8
INPUT
OUTPUT
TEST POINTS
0.45
0530_13
NOTE:
AC test inputs are driven at VOH (2.4 VTTL) for a logic “1” and VOL (0.45 VTTL) for a logic “0.” Input timing begins at VIH (2.0 VTTL
and VIL (0.8 VTTL). Output timing ends at VIH and VIL. Input rise and fall times (10% to 90%) < 10 ns.
)
Figure 21. 5V Input Range and Measurement Points
VCC
Test Configuration Component Values
Test Configuration
CL (pF) R1 (Ω) R2 (Ω)
R
R
2.7V and 3.3V Standard
Test
50
990
770
1
5V Standard Test
100
580
390
DEVICE
UNDER
TEST
OUT
NOTE: CL includes jig capacitance.
C
L
2
0530_14
NOTE: See table for component values.
Figure 22. Test Configuration
50
PRELIMINARY
E
4-MBIT SmartVoltage BOOT BLOCK FAMILY
6.3
AC Characteristics
Table 20. AC Characteristics: Read Only Operations(1) (Extended Temperature)
Prod
TBE-120
TBV-80
TBV-80
TBE-120
Sym
Parameter
VCC
2.7V–3.6V(5) 3.3 ±0.3V(5)
50 pF 50 pF
5V±10%(6)
100 pF
Unit
Load
Notes Min Max Min Max Min Max
tAVAV
tAVQV
tELQV
tPHQV
tGLQV
tELQX
tEHQZ
tGLQX
tGHQZ
tOH
Read Cycle Time
120
110
80
ns
ns
ns
µs
ns
ns
ns
ns
ns
ns
Address to Output Delay
CE# to Output Delay
RP# to Output Delay
OE# to Output Delay
CE# to Output in Low Z
CE# to Output in High Z
OE# to Output in Low Z
OE# to Output in High Z
120
120
0.8
65
110
110
0.8
65
80
80
2
0.45
40
2
3
3
3
3
3
0
0
0
0
0
0
0
0
0
25
25
25
25
20
20
Output Hold from Address, CE#,
or OE# Change, Whichever
Occurs First
tELFL
tELFH
CE# Low to BYTE# High or Low
3
5
5
5
ns
tAVFL
Address to BYTE# High or Low
BYTE# to Output Delay
3
0
0
0
ns
ns
tFLQV
tFHQV
tFLQZ
tPLPH
3,4
120
45
110
45
80
30
BYTE# Low to Output in High Z
Reset Pulse Width Low
3
7
ns
ns
ns
150
150
60
tPLQZ
RP# Low to Output High Z
150
150
60
NOTES:
1. See AC Input/Output Reference Waveform for timing measurements.
2. OE# may be delayed up to tCE–tOE after the falling edge of CE# without impact on tCE
.
3. Sampled, but not 100% tested.
4.
tFLQV, BYTE# switching low to valid output delay will be equal to tAVQV, measured from the time DQ15/A–1 becomes valid.
5. See Test Configurations (Figure 22), 2.7V–3.6V and 3.3 ± 0.3V Standard Test component values.
6. See Test Configurations (Figure 22), 5V Standard Test component values.
7. The specification tPLPH is the minimum time RP# must be held low to produce a valid reset of the device.
51
PRELIMINARY
4-MBIT SmartVoltage BOOT BLOCK FAMILY
E
Table 21. AC Characteristics: WE#-Controlled Write Operations(1) (Extended Temperature)
Prod
TBE-120
TBV-80
TBV-80
TBE-120
Sym
Parameter
VCC
2.7V–3.6V(9) 3.3±0.3V(9) 5V±10%(10)
Unit
Load
50 pF 50 pF 100 pF
Notes Min Max Min Max Min Max
tAVAV
Write Cycle Time
120
0.8
110
0.8
80
ns
tPHWL
RP# High Recovery to WE#
Going Low
0.45
µs
tELWL
CE# Setup to WE# Going Low
0
0
0
ns
ns
tPHHWH
Boot Block Lock Setup to WE#
Going High
6,8
5,8
3
200
200
100
tVPWH
VPP Setup to WE#
Going High
200
90
200
90
100
60
ns
ns
tAVWH
Address Setup to WE# Going
High
tDVWH
tWLWH
tWHDX
tWHAX
Data Setup to WE# Going High
WE# Pulse Width
4
70
90
0
70
90
0
60
60
0
ns
ns
ns
ns
Data Hold Time from WE# High
4
3
Address Hold Time from WE#
High
0
0
0
tWHEH
tWHWL
tWHQV1
tWHQV2
CE# Hold Time from WE# High
WE# Pulse Width High
0
30
6
0
20
6
0
20
6
ns
ns
µs
s
Word/Byte Program Time
Erase Duration (Boot)
2,5,8
2,5,
6, 8
0.3
0.3
0.3
Erase Duration (Param)
Erase Duration (Main)
tWHQV3
tWHQV4
tQVVL
2,5,8
2,5,8
5,8
0.3
0.6
0
0.3
0.6
0
0.3
0.6
0
s
s
VPP Hold from Valid SRD
RP# VHH Hold from Valid SRD
Boot-Block Lock Delay
ns
ns
ns
tQVPH
tPHBR
6,8
0
0
0
7,8
200
200
100
52
PRELIMINARY
E
4-MBIT SmartVoltage BOOT BLOCK FAMILY
NOTES:
1. Read timing characteristics during program and erase operations are the same as during read-only operations. Refer to AC
Characteristics during read mode.
2. The on-chip WSM completely automates program/erase operations; program/erase algorithms are now controlled internally
which includes verify and margining operations.
3. Refer to command definition table for valid A . (Table 7)
IN
4. Refer to command definition table for valid D . (Table 7)
IN
5. Program/erase durations are measured to valid SRD data (successful operation, SR.7 = 1)
6. For boot block program/erase, RP# should be held at VHH or WP# should be held at VIH until operation completes
successfully.
7. Time tPHBR is required for successful locking of the boot block.
8. Sampled, but not 100% tested.
9. See Test Configurations (Figure 22), 2.7V–3.6V and 3.3 ± 0.3V Standard Test component values.
10. See Test Configurations (Figure 22), 5V Standard Test component values.
53
PRELIMINARY
4-MBIT SmartVoltage BOOT BLOCK FAMILY
E
Table 22. AC Characteristics: CE#–Controlled Write Operations (1,11) (Extended Temperature)
Prod
TBE-120
TBV-80
TBV-80
TBE-120
Sym
Parameter
VCC
2.7V–3.6V(9) 3.3 ±0.3V(9) 5V±10%(10)
Unit
Load
50 pF 50 pF 100 pF
Notes Min Max Min Max Min Max
tAVAV
Write Cycle Time
120
0.8
110
0.8
80
ns
tPHEL
RP# High Recovery to CE#
Going Low
0.45
µs
tWLEL
WE# Setup to CE# Going Low
0
0
0
ns
ns
tPHHEH
Boot Block Lock Setup to CE#
Going High
6,8
5,8
200
200
100
tVPEH
tAVEH
VPP Setup to CE# Going High
200
90
200
90
100
60
ns
ns
Address Setup to CE# Going
High
tDVEH
tELEH
tEHDX
tEHAX
Data Setup to CE# Going High
CE# Pulse Width
3
4
70
90
0
70
90
0
60
60
0
ns
ns
ns
ns
Data Hold Time from CE# High
Address Hold Time from CE#
High
4
3
0
0
0
tEHWH
tEHEL
WE# Hold Time from CE# High
CE# Pulse Width High
0
20
6
0
20
6
0
20
6
ns
ns
µs
s
tEHQV1
tEHQV2
tEHQV3
tEHQV4
tQVVL
Word/Byte Program Time
Erase Duration (Boot)
2,5
2,5,6
2,5
0.3
0.3
0.6
0
0.3
0.3
0.6
0
0.3
0.3
0.6
0
Erase Duration (Param)
Erase Duration (Main)
s
2,5
s
VPP Hold from Valid SRD
RP# VHH Hold from Valid SRD
Boot-Block Lock Delay
5,8
ns
ns
ns
tQVPH
6,8
0
0
0
tPHBR
7,8
200
200
100
NOTES:
See WE# Controlled Write Operations for notes 1 through 10.
11. Chip-Enable controlled writes: write operations are driven by the valid combination of CE# and WE# in systems where CE#
defines the write pulse-width (within a longer WE# timing waveform), all set-up, hold and inactive WE# times should be
measured relative to the CE# waveform.
54
PRELIMINARY
E
4-MBIT SmartVoltage BOOT BLOCK FAMILY
Table 23. Erase and Program Timings (Extended TA = –40°C to +85°C)
5V ± 10%
3.3 ± 0.3V
12V ± 5%
3.3 ± 0.3V
VPP
VCC
Parameter
2.7V–3.6V
5V ± 10%
2.7V–3.6V
5V ± 10%
Typ Max Typ Max Typ Max Typ Max Typ Max Typ Max Unit
Boot/Parameter
Block Erase Time
0.88
7
0.84
7
0.8
1.9
1.4
7
0.46
1.36
1.76
7
0.44
7
0.34
7
s
s
s
Main Block
Erase Time
2.5
14
2.4
14
14
14
1.3
14
1.1
14
Main Block
1.87
1.7
1.6
1.2
Program Time
(Byte Mode)
0.88
Main Block
1.21
1.1
0.9
0.8
0.6
s
Program Time
(Word Mode)
8.8
Byte Program
Time(4)
11
10
10
8
8
µs
µs
8.8
Word Program
Time(4)
14.3
13
13
8
8
NOTES:
1. All numbers are sampled, not 100% tested.
2. Max erase times are specified under worst case conditions. The max erase times are tested at the same value
independent of VCC and VPP. See Note 3 for typical conditions.
3. Typical conditions are +25°C with VCC and VPP at the center of the specifed voltage range. Production programming using
CC = 5.0V, VPP = 12.0V typically results in a 60% reduction in programming time.
V
4. Contact your Intel field representative for more information.
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PRELIMINARY
4-MBIT SmartVoltage BOOT BLOCK FAMILY
E
APPENDIX A
ORDERING INFORMATION
T E2 8F4 0 0CV - T8 0
(ns)
Access Speed
Operating Temperature
= Extended Temp
VCC = 5V
BV/CV:
BE/CE:
T
VCC = 2.7V
= Commercial Temp
Blank
Top Boot
T =
Package
B = Bottom Boot
= TSOP
E
(VPP/VCC
= (5 or 12 / 3.3 or 5)
= (5 or 12 / 2.7 or 5)
)
Voltage Options
V
E
= 44-Lead PSOP
PA
TB
= Ext. Temp 44-Lead PSOP
Product line designator
for all Intel Flash products
Architecture
= Boot Block
= Compact 48-Lead TSOP
Boot Block
B
C
Density / Organization
= x8-only (X = 1, 2, 4, 8)
00X
X00
= x8/x16 Selectable (X = 2, 4, 8)
0530_23
VALID COMBINATIONS:
40-Lead TSOP
44-Lead PSOP
48-Lead TSOP
56-Lead TSOP
Commercial
Extended
E28F004BVT60
E28F004BVB60
E28F004BVT80
E28F004BVB80
E28F004BVT120
E28F004BVB120
PA28F400BVT60
PA28F400BVB60
PA28F400BVT80
PA28F400BVB80
PA28F400BVT120
PA28F400BVB120
E28F400CVT60
E28F400CVB60
E28F400CVT80
E28F400CVB80
E28F400BVT60
E28F400BVB60
E28F400BVT80
E28F400BVB80
TE28F004BVT80
TE28F004BVB80
TB28F400BVT80
TB28F400BVB80
TE28F400CVT80
TE28F400CVB80
TE28F400BVT80
TE28F400BVB80
TE28F004BET120
TE28F004BEB120
TE28F400CET120
TE28F400CEB120
Table 24. Summary of Line Items
VPP 40-Ld 44-Ld 48-Ld 56-Ld
5V 12V TSOP PSOP TSOP TSOP
VCC
0°C –
–40°C –
Name
2.7V 3.3V 5V
+70°C
+85°C
28F004BV
28F400BV
28F400CV
28F004BE
28F400CE
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
56
PRELIMINARY
E
4-MBIT SmartVoltage BOOT BLOCK FAMILY
APPENDIX B
ADDITIONAL INFORMATION
(1,2)
RELATED INTEL INFORMATION
Order
Number
Document
290599
292194
292154
290531
290539
292164
Smart 5 Boot Block Flash Memory Family 2, 4, 8 Mbit Datasheet
AB-65 Migrating Designs from SmartVoltage Boot Block to Smart 5 Flash
AB-60 2/4/8-Mbit SmartVoltage Boot Block Flash Memory Family
2-Mbit SmartVoltage Boot Block Flash Memory Family Datasheet
8-Mbit SmartVoltage Boot Block Flash Memory Family Datasheet
AP-611 2/4M Boot Block Compatibility with 2/4/8-M SmartVoltage Boot Block Flash
Memories
290448
290449
290451
290450
292148
292172
292130
28F002/200BX-T/B 2-Mbit Boot Block Flash Memory Datasheet
28F002/200BL-T/B 2-Mbit Low Power Boot Block Flash Memory Datasheet
28F004/400BX-T/B 4-Mbit Boot Block Flash Memory Datasheet
28F004/400BL-T/B 4-Mbit Low Power Boot Block Flash Memory Datasheet
AP-604 Using Intel’s Boot Block Flash Memory Parameter Blocks to Replace EEPROM
AP-617 Additional Flash Data Protection Using VPP, RP#, and WP#
AB-57 Boot Block Architecture for Safe Firmware Updates
NOTES:
1. Please call the Intel Literature Center at (800) 548-4725 to request Intel documentation. International customers should
contact their local Intel or distribution sales office.
2. Visit Intel’s World Wide Web home page at http://www.Intel.com for technical documentation and tools.
57
PRELIMINARY
相关型号:
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